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To all our customers Regarding the change of names mentioned in the document, such as Hitachi Electric and Hitachi XX, to Renesas Technology Corp. The semiconductor operations of Mitsubishi Electric and Hitachi were transferred to Renesas Technology Corporation on April 1st 2003. These operations include microcomputer, logic, analog and discrete devices, and memory chips other than DRAMs (flash memory, SRAMs etc.) Accordingly, although Hitachi, Hitachi, Ltd., Hitachi Semiconductors, and other Hitachi brand names are mentioned in the document, these names have in fact all been changed to Renesas Technology Corp. Thank you for your understanding. Except for our corporate trademark, logo and corporate statement, no changes whatsoever have been made to the contents of the document, and these changes do not constitute any alteration to the contents of the document itself. w w w .D at Sh a et e 4U . om c Renesas Technology Home Page: www.renesas.com w w w .D t a S a e h Renesas Technology Corp. Customer Support Dept. April 1, 2003 t e U 4 .c m o w Renesas Technology Corp. w w .D at Sh a et e 4U . om c Hitachi Single-Chip Microcomputer H8/3052 F-ZTATTM HD64F3052TE, HD64F3052F, HD64F3052BTE, HD64F3052BF, HD64F3052BVTE, HD64F3052BVF Hardware Manual ADE-602-180A Rev. 2.0 3/23/2001 Hitachi, Ltd. Cautions 1. Hitachi neither warrants nor grants licenses of any rights of Hitachi's or any third party's patent, copyright, trademark, or other intellectual property rights for information contained in this document. Hitachi bears no responsibility for problems that may arise with third party's rights, including intellectual property rights, in connection with use of the information contained in this document. 2. Products and product specifications may be subject to change without notice. Confirm that you have received the latest product standards or specifications before final design, purchase or use. 3. Hitachi makes every attempt to ensure that its products are of high quality and reliability. However, contact Hitachi's sales office before using the product in an application that demands especially high quality and reliability or where its failure or malfunction may directly threaten human life or cause risk of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment or medical equipment for life support. 4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly for maximum rating, operating supply voltage range, heat radiation characteristics, installation conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as fail-safes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other consequential damage due to operation of the Hitachi product. 5. This product is not designed to be radiation resistant. 6. No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without written approval from Hitachi. 7. Contact Hitachi's sales office for any questions regarding this document or Hitachi semiconductor products. Preface The H8/3052F is a series of high-performance microcontrollers that integrate system supporting functions together with an H8/300H CPU core. The H8/300H CPU has a 32-bit internal architecture with sixteen 16-bit general registers, and a concise, optimized instruction set designed for speed. It can address a 16-Mbyte linear address space. The on-chip supporting functions include ROM, RAM, a 16-bit integrated timer unit (ITU), a programmable timing pattern controller (TPC), a watchdog timer (WDT), a serial communication interface (SCI), an A/D converter, a D/A converter, I/O ports, a direct memory access controller (DMAC), a refresh controller, and other facilities. Of the two SCI channels, one has been expanded to support the ISO/IEC7816-3 smart card interface. Functions have also been added to reduce power consumption in battery-powered applications: individual modules can be placed in standby, and the frequency of the system clock supplied to the chip can be divided down under software control. The address space is divided into eight areas. The data bus width and access cycle length can be selected independently in each area, simplifying the connection of different types of memory. Seven operating modes (modes 1 to 7) are provided, offering a choice of data bus width and address space size. With these features, the H8/3052F can be used to implement compact, high-performance systems easily. The H8/3052F has an F-ZTATTM* version with on-chip flash memory that can be programmed on-board. These versions enable users to respond quickly and flexibly to changing application specifications. This manual describes the H8/3052F hardware. For details of the instruction set, refer to the H8/300H Series Programming Manual. Note: * F-ZTATTM (Flexible-Zero Turn Around Time) is a trademark of Hitachi, Ltd. Rev. 2.0, 03/01, page iii of 20 Rev. 2.0, 03/01, page iv of 20 List of Items Revised or Added for This Version Section All Page # Item Description Amendments due to introduction of the H8/3052F-ZTAT B mask version. Table 1.1 Feature Figure1.1 Block Diagram Table 1.2 Pin Assignments in Each Mode(FP-100B or TFP-100B) Table1.3 Pin Functions Table 18.12 H8/3052F Socket Adapter Product Codes 19.2.1 Connecting a Crystal Resonator "Circuit Configuration" Figure 19.2 Connecting of Crystal Resonator (Example) Table 19.1(1) Damping Resistance Value Table 19.1(2) External Capacitance Values 612 19.2.2 External Clock Input 21.1 Absolute Maximum Ratings 614 635 637 639, 640 641 21.2.2 AC Characteristics 643, 644 645 646 Table 19.2 Crystal Resonator Parameters Table 19.3 Clock Timing Table 21.1 Absolute Maximum Ratings Table 21.2 (1)DC Characteristics Table 21.2(2) DC Characteristics Table 21.3 Permissible Output Currents Table 21.4 Bus Timing Table 21.5 Refresh Controller Bus Timing Table 21.6 Control Signal Timing Amended 25 MHz added Added 20 and 25 MHz added Amended Amended Current dissipation amended Added Conditions amended Amended Amended Amended Product lineup amended VCL amended to VCL/VCC Pin 1 and note 1 amended Note added Product codes added 1.1 Overview 1.2 Block Diagram 1.3.2 Pin Assignments in Each Mode 1.3.3 Pin Functions 18.10.1 Socket Adapters and Memory Map 19.2 Oscillator Circuit 5 6 8,12 17 603 611 Description added Rev. 2.0, 03/01, page v of 20 Section 21.2.2 AC Characteristics 21.2.3 A/D Conversion Characteristics 21.2.4 D/A Conversion Characteristics 21.2.5 Flash Memory Characteristics Appendix F Product Code Lineup Appendix H Differences from H8/3048F-ZTAT Page 647 649 Item Table 21.7 Timing of On-Chip Supporting Modules Table 21.8 A/D Converter Characteristics Table 21.9 D/A Converter Characteristics Table 21.10 Flash Memory Characteristics Table F.1 H8/3052F Product Code Lineup Table H.1 Differences between H8/3052F-ZTAT and H8/3048F-ZTAT Description Amended Amended 650 Amended 651 Conditions amended 816 819 Product types added H8/3052F-ZTAT pin specifications amended Rev. 2.0, 03/01, page vi of 20 Contents Section 1 1.1 1.2 1.3 Overview........................................................................................................... 1 Overview........................................................................................................................... 1 Block Diagram .................................................................................................................. 6 Pin Description.................................................................................................................. 7 1.3.1 Pin Arrangement .................................................................................................. 7 1.3.2 Pin Assignments in Each Mode ........................................................................... 8 1.3.3 Pin Functions ....................................................................................................... 13 CPU.................................................................................................................... 19 19 19 20 21 22 23 23 24 25 26 27 27 29 30 30 31 32 42 43 44 44 47 51 51 52 52 54 55 55 55 Section 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Overview........................................................................................................................... 2.1.1 Features................................................................................................................ 2.1.2 Differences from H8/300 CPU ............................................................................ CPU Operating Modes ...................................................................................................... Address Space................................................................................................................... Register Configuration...................................................................................................... 2.4.1 Overview.............................................................................................................. 2.4.2 General Registers ................................................................................................. 2.4.3 Control Registers ................................................................................................. 2.4.4 Initial CPU Register Values................................................................................. Data Formats..................................................................................................................... 2.5.1 General Register Data Formats ............................................................................ 2.5.2 Memory Data Formats ......................................................................................... Instruction Set ................................................................................................................... 2.6.1 Instruction Set Overview ..................................................................................... 2.6.2 Instructions and Addressing Modes..................................................................... 2.6.3 Tables of Instructions Classified by Function...................................................... 2.6.4 Basic Instruction Formats .................................................................................... 2.6.5 Notes on Use of Bit Manipulation Instructions.................................................... Addressing Modes and Effective Address Calculation ..................................................... 2.7.1 Addressing Modes ............................................................................................... 2.7.2 Effective Address Calculation ............................................................................. Processing States............................................................................................................... 2.8.1 Overview.............................................................................................................. 2.8.2 Program Execution State...................................................................................... 2.8.3 Exception-Handling State .................................................................................... 2.8.4 Exception-Handling Sequences ........................................................................... 2.8.5 Bus-Released State............................................................................................... 2.8.6 Reset State............................................................................................................ 2.8.7 Power-Down State ............................................................................................... Rev. 2.0, 03/01, page vii of 20 2.9 Basic Operational Timing ................................................................................................. 2.9.1 Overview.............................................................................................................. 2.9.2 On-Chip Memory Access Timing........................................................................ 2.9.3 On-Chip Supporting Module Access Timing ...................................................... 2.9.4 Access to External Address Space ....................................................................... 56 56 56 57 58 Section 3 3.1 MCU Operating Modes................................................................................ 59 59 59 60 60 61 63 63 63 63 63 63 64 64 64 65 69 69 69 69 70 72 72 72 75 76 77 77 78 3.2 3.3 3.4 3.5 3.6 Overview........................................................................................................................... 3.1.1 Operating Mode Selection ................................................................................... 3.1.2 Register Configuration......................................................................................... Mode Control Register (MDCR) ...................................................................................... System Control Register (SYSCR) ................................................................................... Operating Mode Descriptions ........................................................................................... 3.4.1 Mode 1 ................................................................................................................. 3.4.2 Mode 2 ................................................................................................................. 3.4.3 Mode 3 ................................................................................................................. 3.4.4 Mode 4 ................................................................................................................. 3.4.5 Mode 5 ................................................................................................................. 3.4.6 Mode 6 ................................................................................................................. 3.4.7 Mode 7 ................................................................................................................. Pin Functions in Each Operating Mode ............................................................................ Memory Map in Each Operating Mode ............................................................................ Section 4 4.1 4.2 4.3 4.4 4.5 4.6 Exception Handling ....................................................................................... Overview........................................................................................................................... 4.1.1 Exception Handling Types and Priority............................................................... 4.1.2 Exception Handling Operation ............................................................................ 4.1.3 Exception Sources and Vector Table ................................................................... Reset ................................................................................................................................. 4.2.1 Overview.............................................................................................................. 4.2.2 Reset Sequence .................................................................................................... 4.2.3 Interrupts after Reset............................................................................................ Interrupts........................................................................................................................... Trap Instruction................................................................................................................. Stack Status after Exception Handling.............................................................................. Notes on Use of the Stack ................................................................................................. Section 5 5.1 Interrupt Controller........................................................................................ 79 79 79 80 81 81 Overview........................................................................................................................... 5.1.1 Features................................................................................................................ 5.1.2 Block Diagram..................................................................................................... 5.1.3 Pin Configuration................................................................................................. 5.1.4 Register Configuration......................................................................................... Rev. 2.0, 03/01, page viii of 20 5.2 5.3 5.4 5.5 Register Descriptions ........................................................................................................ 5.2.1 System Control Register (SYSCR) ...................................................................... 5.2.2 Interrupt Priority Registers A and B (IPRA, IPRB)............................................. 5.2.3 IRQ Status Register (ISR).................................................................................... 5.2.4 IRQ Enable Register (IER) .................................................................................. 5.2.5 IRQ Sense Control Register (ISCR) .................................................................... Interrupt Sources............................................................................................................... 5.3.1 External Interrupts ............................................................................................... 5.3.2 Internal Interrupts ................................................................................................ 5.3.3 Interrupt Exception Vector Table ........................................................................ Interrupt Operation............................................................................................................ 5.4.1 Interrupt Handling Process .................................................................................. 5.4.2 Interrupt Exception Handling Sequence ............................................................. 5.4.3 Interrupt Response Time...................................................................................... Usage Notes ...................................................................................................................... 5.5.1 Contention between Interrupt Generation and Disabling..................................... 5.5.2 Instructions that Inhibit Interrupts........................................................................ 5.5.3 Interrupts during EEPMOV Instruction Execution.............................................. 5.5.4 Notes on Use of External Interrupts..................................................................... 82 82 83 90 91 92 93 93 94 94 98 98 103 104 105 105 106 106 106 109 109 109 110 111 112 112 112 113 114 115 116 118 119 119 121 122 123 131 137 139 142 142 Section 6 6.1 6.2 6.3 6.4 Bus Controller ................................................................................................. Overview........................................................................................................................... 6.1.1 Features................................................................................................................ 6.1.2 Block Diagram..................................................................................................... 6.1.3 Pin Configuration................................................................................................. 6.1.4 Register Configuration......................................................................................... Register Descriptions ........................................................................................................ 6.2.1 Bus Width Control Register (ABWCR)............................................................... 6.2.2 Access State Control Register (ASTCR) ............................................................. 6.2.3 Wait Control Register (WCR).............................................................................. 6.2.4 Wait State Controller Enable Register (WCER) .................................................. 6.2.5 Bus Release Control Register (BRCR) ................................................................ 6.2.6 Chip Select Control Register (CSCR).................................................................. Operation .......................................................................................................................... 6.3.1 Area Division....................................................................................................... 6.3.2 Chip Select Signals .............................................................................................. 6.3.3 Data Bus............................................................................................................... 6.3.4 Bus Control Signal Timing .................................................................................. 6.3.5 Wait Modes.......................................................................................................... 6.3.6 Interconnections with Memory (Example) .......................................................... 6.3.7 Bus Arbiter Operation.......................................................................................... Usage Notes ...................................................................................................................... 6.4.1 Connection to Dynamic RAM and Pseudo-Static RAM...................................... Rev. 2.0, 03/01, page ix of 20 6.4.2 6.4.3 6.4.4 Register Write Timing ......................................................................................... 142 %5(4 Input Timing............................................................................................. 144 Transition To Software Standby Mode................................................................ 144 Section 7 7.1 Refresh Controller.......................................................................................... 145 145 145 147 148 148 149 149 152 153 154 155 155 157 172 176 182 182 185 185 185 186 187 189 189 191 192 193 194 195 198 198 199 199 201 206 206 208 7.2 7.3 7.4 7.5 Overview........................................................................................................................... 7.1.1 Features................................................................................................................ 7.1.2 Block Diagram..................................................................................................... 7.1.3 Pin Configuration................................................................................................. 7.1.4 Register Configuration......................................................................................... Register Descriptions ........................................................................................................ 7.2.1 Refresh Control Register (RFSHCR)................................................................... 7.2.2 Refresh Timer Control/Status Register (RTMCSR) ............................................ 7.2.3 Refresh Timer Counter (RTCNT)........................................................................ 7.2.4 Refresh Time Constant Register (RTCOR) ......................................................... Operation .......................................................................................................................... 7.3.1 Overview.............................................................................................................. 7.3.2 DRAM Refresh Control....................................................................................... 7.3.3 Pseudo-Static RAM Refresh Control ................................................................... 7.3.4 Interval Timing .................................................................................................... Interrupt Source ................................................................................................................ Usage Notes ...................................................................................................................... Section 8 8.1 8.2 8.3 8.4 DMA Controller ............................................................................................. Overview........................................................................................................................... 8.1.1 Features................................................................................................................ 8.1.2 Block Diagram..................................................................................................... 8.1.3 Functional Overview............................................................................................ 8.1.4 Pin Configuration................................................................................................. 8.1.5 Register Configuration......................................................................................... Register Descriptions (Short Address Mode).................................................................... 8.2.1 Memory Address Registers (MAR) ..................................................................... 8.2.2 I/O Address Registers (IOAR) ............................................................................. 8.2.3 Execute Transfer Count Registers (ETCR).......................................................... 8.2.4 Data Transfer Control Registers (DTCR) ............................................................ Register Descriptions (Full Address Mode)...................................................................... 8.3.1 Memory Address Registers (MAR) ..................................................................... 8.3.2 I/O Address Registers (IOAR) ............................................................................. 8.3.3 Execute Transfer Count Registers (ETCR).......................................................... 8.3.4 Data Transfer Control Registers (DTCR) ............................................................ Operation .......................................................................................................................... 8.4.1 Overview.............................................................................................................. 8.4.2 I/O Mode.............................................................................................................. Rev. 2.0, 03/01, page x of 20 8.5 8.6 8.4.3 Idle Mode............................................................................................................. 8.4.4 Repeat Mode ........................................................................................................ 8.4.5 Normal Mode....................................................................................................... 8.4.6 Block Transfer Mode ........................................................................................... 8.4.7 DMAC Activation................................................................................................ 8.4.8 DMAC Bus Cycle ................................................................................................ 8.4.9 DMAC Multiple-Channel Operation ................................................................... 8.4.10 External Bus Requests, Refresh Controller, and DMAC ..................................... 8.4.11 NMI Interrupts and DMAC ................................................................................. 8.4.12 Aborting a DMA Transfer ................................................................................... 8.4.13 Exiting Full Address Mode.................................................................................. 8.4.14 DMAC States in Reset State, Standby Modes, and Sleep Mode ......................... Interrupts........................................................................................................................... Usage Notes ...................................................................................................................... 8.6.1 Note on Word Data Transfer................................................................................ 8.6.2 DMAC Self-Access ............................................................................................. 8.6.3 Longword Access to Memory Address Registers ................................................ 8.6.4 Note on Full Address Mode Setup....................................................................... 8.6.5 Note on Activating DMAC by Internal Interrupts ............................................... 8.6.6 NMI Interrupts and Block Transfer Mode ........................................................... 8.6.7 Memory and I/O Address Register Values .......................................................... 8.6.8 Bus Cycle when Transfer is Aborted ................................................................... 210 213 217 220 225 227 233 234 235 236 237 238 239 240 240 240 240 240 240 242 242 243 Section 9 9.1 9.2 I/O Ports............................................................................................................ 245 245 249 249 250 252 252 253 256 256 256 258 258 259 262 262 263 266 266 267 9.3 9.4 9.5 9.6 9.7 Overview........................................................................................................................... Port 1................................................................................................................................. 9.2.1 Overview.............................................................................................................. 9.2.2 Register Configuration......................................................................................... Port 2................................................................................................................................. 9.3.1 Overview.............................................................................................................. 9.3.2 Register Configuration......................................................................................... Port 3................................................................................................................................. 9.4.1 Overview.............................................................................................................. 9.4.2 Register Configuration......................................................................................... Port 4................................................................................................................................. 9.5.1 Overview.............................................................................................................. 9.5.2 Register Configuration......................................................................................... Port 5................................................................................................................................. 9.6.1 Overview.............................................................................................................. 9.6.2 Register Configuration......................................................................................... Port 6................................................................................................................................. 9.7.1 Overview.............................................................................................................. 9.7.2 Register Configuration......................................................................................... Rev. 2.0, 03/01, page xi of 20 9.8 Port 7................................................................................................................................. 9.8.1 Overview.............................................................................................................. 9.8.2 Register Configuration......................................................................................... 9.9 Port 8................................................................................................................................. 9.9.1 Overview.............................................................................................................. 9.9.2 Register Configuration......................................................................................... 9.10 Port 9................................................................................................................................. 9.10.1 Overview.............................................................................................................. 9.10.2 Register Configuration......................................................................................... 9.11 Port A................................................................................................................................ 9.11.1 Overview.............................................................................................................. 9.11.2 Register Configuration......................................................................................... 9.11.3 Pin Functions ....................................................................................................... 9.12 Port B ................................................................................................................................ 9.12.1 Overview.............................................................................................................. 9.12.2 Register Configuration......................................................................................... 9.12.3 Pin Functions ....................................................................................................... 270 270 271 272 272 273 277 277 278 282 282 284 286 294 294 296 298 Section 10 16-Bit Integrated Timer Unit (ITU).......................................................... 305 10.1 Overview........................................................................................................................... 10.1.1 Features................................................................................................................ 10.1.2 Block Diagrams ................................................................................................... 10.1.3 Pin Configuration................................................................................................. 10.1.4 Register Configuration......................................................................................... 10.2 Register Descriptions ........................................................................................................ 10.2.1 Timer Start Register (TSTR)................................................................................ 10.2.2 Timer Synchro Register (TSNC) ......................................................................... 10.2.3 Timer Mode Register (TMDR) ............................................................................ 10.2.4 Timer Function Control Register (TFCR)............................................................ 10.2.5 Timer Output Master Enable Register (TOER) ................................................... 10.2.6 Timer Output Control Register (TOCR) .............................................................. 10.2.7 Timer Counters (TCNT) ...................................................................................... 10.2.8 General Registers (GRA, GRB)........................................................................... 10.2.9 Buffer Registers (BRA, BRB) ............................................................................. 10.2.10 Timer Control Registers (TCR) ........................................................................... 10.2.11 Timer I/O Control Register (TIOR) ..................................................................... 10.2.12 Timer Status Register (TSR)................................................................................ 10.2.13 Timer Interrupt Enable Register (TIER) .............................................................. 10.3 CPU Interface.................................................................................................................... 10.3.1 16-Bit Accessible Registers ................................................................................. 10.3.2 8-Bit Accessible Registers ................................................................................... 10.4 Operation .......................................................................................................................... 10.4.1 Overview.............................................................................................................. Rev. 2.0, 03/01, page xii of 20 305 305 308 313 314 317 317 318 320 323 325 327 328 329 330 331 333 335 337 339 339 341 343 343 10.4.2 Basic Functions.................................................................................................... 10.4.3 Synchronization ................................................................................................... 10.4.4 PWM Mode.......................................................................................................... 10.4.5 Reset-Synchronized PWM Mode......................................................................... 10.4.6 Complementary PWM Mode............................................................................... 10.4.7 Phase Counting Mode.......................................................................................... 10.4.8 Buffering.............................................................................................................. 10.4.9 ITU Output Timing .............................................................................................. 10.5 Interrupts........................................................................................................................... 10.5.1 Setting of Status Flags ......................................................................................... 10.5.2 Clearing of Status Flags ....................................................................................... 10.5.3 Interrupt Sources and DMA Controller Activation.............................................. 10.6 Usage Notes ...................................................................................................................... 344 353 355 359 362 371 373 380 382 382 384 385 386 Section 11 Programmable Timing Pattern Controller............................................... 401 11.1 Overview........................................................................................................................... 11.1.1 Features................................................................................................................ 11.1.2 Block Diagram..................................................................................................... 11.1.3 Pin Configuration................................................................................................. 11.1.4 Register Configuration......................................................................................... 11.2 Register Descriptions ........................................................................................................ 11.2.1 Port A Data Direction Register (PADDR) ........................................................... 11.2.2 Port A Data Register (PADR).............................................................................. 11.2.3 Port B Data Direction Register (PBDDR) ........................................................... 11.2.4 Port B Data Register (PBDR) .............................................................................. 11.2.5 Next Data Register A (NDRA) ............................................................................ 11.2.6 Next Data Register B (NDRB)............................................................................. 11.2.7 Next Data Enable Register A (NDERA).............................................................. 11.2.8 Next Data Enable Register B (NDERB) .............................................................. 11.2.9 TPC Output Control Register (TPCR) ................................................................. 11.2.10 TPC Output Mode Register (TPMR) ................................................................... 11.3 Operation .......................................................................................................................... 11.3.1 Overview.............................................................................................................. 11.3.2 Output Timing ..................................................................................................... 11.3.3 Normal TPC Output............................................................................................. 11.3.4 Non-Overlapping TPC Output............................................................................. 11.3.5 TPC Output Triggering by Input Capture ............................................................ 11.4 Usage Notes ...................................................................................................................... 11.4.1 Operation of TPC Output Pins ............................................................................. 11.4.2 Note on Non-Overlapping Output........................................................................ 401 401 402 403 404 405 405 405 406 406 407 409 411 412 413 415 417 417 418 419 421 423 424 424 424 Rev. 2.0, 03/01, page xiii of 20 Section 12 Watchdog Timer............................................................................................. 427 12.1 Overview........................................................................................................................... 12.1.1 Features................................................................................................................ 12.1.2 Block Diagram..................................................................................................... 12.1.3 Register Configuration......................................................................................... 12.2 Register Descriptions ........................................................................................................ 12.2.1 Timer Counter (TCNT)........................................................................................ 12.2.2 Timer Control/Status Register (TCSR)................................................................ 12.2.3 Reset Control/Status Register (RSTCSR) ............................................................ 12.2.4 Notes on Register Access..................................................................................... 12.3 Operation .......................................................................................................................... 12.3.1 Watchdog Timer Operation ................................................................................. 12.3.2 Interval Timer Operation ..................................................................................... 12.3.3 Timing of Setting of Overflow Flag (OVF)......................................................... 12.3.4 Timing of Setting of Watchdog Timer Reset Bit (WRST) .................................. 12.4 Interrupts........................................................................................................................... 12.5 Usage Notes ...................................................................................................................... 427 427 428 428 429 429 430 432 433 434 434 435 435 436 437 437 Section 13 Serial Communication Interface ................................................................ 439 13.1 Overview........................................................................................................................... 13.1.1 Features................................................................................................................ 13.1.2 Block Diagram..................................................................................................... 13.1.3 Pin Configuration................................................................................................. 13.1.4 Register Configuration......................................................................................... 13.2 Register Descriptions ........................................................................................................ 13.2.1 Receive Shift Register (RSR) .............................................................................. 13.2.2 Receive Data Register (RDR) .............................................................................. 13.2.3 Transmit Shift Register (TSR) ............................................................................. 13.2.4 Transmit Data Register (TDR)............................................................................. 13.2.5 Serial Mode Register (SMR)................................................................................ 13.2.6 Serial Control Register (SCR).............................................................................. 13.2.7 Serial Status Register (SSR) ................................................................................ 13.2.8 Bit Rate Register (BRR) ...................................................................................... 13.3 Operation .......................................................................................................................... 13.3.1 Overview.............................................................................................................. 13.3.2 Operation in Asynchronous Mode ....................................................................... 13.3.3 Multiprocessor Communication........................................................................... 13.3.4 Synchronous Operation........................................................................................ 13.4 SCI Interrupts.................................................................................................................... 13.5 Usage Notes ...................................................................................................................... 439 439 441 442 442 443 443 443 444 444 445 448 452 456 466 466 468 477 484 492 493 Rev. 2.0, 03/01, page xiv of 20 Section 14 Smart Card Interface ..................................................................................... 499 14.1 Overview........................................................................................................................... 14.1.1 Features................................................................................................................ 14.1.2 Block Diagram..................................................................................................... 14.1.3 Pin Configuration................................................................................................. 14.1.4 Register Configuration......................................................................................... 14.2 Register Descriptions ........................................................................................................ 14.2.1 Smart Card Mode Register (SCMR) .................................................................... 14.2.2 Serial Status Register (SSR) ................................................................................ 14.2.3 Serial Mode Register (SMR)................................................................................ 14.2.4 Serial Control Register (SCR).............................................................................. 14.3 Operation .......................................................................................................................... 14.3.1 Overview.............................................................................................................. 14.3.2 Pin Connections ................................................................................................... 14.3.3 Data Format ......................................................................................................... 14.3.4 Register Settings .................................................................................................. 14.3.5 Clock.................................................................................................................... 14.3.6 Transmitting and Receiving Data ........................................................................ 14.4 Usage Notes ...................................................................................................................... 499 499 500 501 501 502 502 503 505 506 507 507 507 509 510 512 514 521 Section 15 A/D Converter................................................................................................. 525 15.1 Overview........................................................................................................................... 15.1.1 Features................................................................................................................ 15.1.2 Block Diagram..................................................................................................... 15.1.3 Pin Configuration................................................................................................. 15.1.4 Register Configuration......................................................................................... 15.2 Register Descriptions ........................................................................................................ 15.2.1 A/D Data Registers A to D (ADDRA to ADDRD) ............................................. 15.2.2 A/D Control/Status Register (ADCSR) ............................................................... 15.2.3 A/D Control Register (ADCR) ............................................................................ 15.3 CPU Interface.................................................................................................................... 15.4 Operation .......................................................................................................................... 15.4.1 Single Mode (SCAN = 0) .................................................................................... 15.4.2 Scan Mode (SCAN = 1)....................................................................................... 15.4.3 Input Sampling and A/D Conversion Time ......................................................... 15.4.4 External Trigger Input Timing............................................................................. 15.5 Interrupts........................................................................................................................... 15.6 Usage Notes ...................................................................................................................... 525 525 526 527 528 529 529 530 532 533 534 534 536 538 539 540 540 Section 16 D/A Converter................................................................................................. 547 16.1 Overview........................................................................................................................... 547 16.1.1 Features................................................................................................................ 547 16.1.2 Block Diagram..................................................................................................... 548 Rev. 2.0, 03/01, page xv of 20 16.1.3 Pin Configuration................................................................................................. 16.1.4 Register Configuration......................................................................................... 16.2 Register Descriptions ........................................................................................................ 16.2.1 D/A Data Registers 0 and 1 (DADR0/1).............................................................. 16.2.2 D/A Control Register (DACR) ............................................................................ 16.2.3 D/A Standby Control Register (DASTCR).......................................................... 16.3 Operation .......................................................................................................................... 16.4 D/A Output Control .......................................................................................................... 549 549 550 550 550 552 553 554 Section 17 RAM .................................................................................................................. 555 17.1 Overview........................................................................................................................... 17.1.1 Block Diagram..................................................................................................... 17.1.2 Register Configuration......................................................................................... 17.2 System Control Register (SYSCR) ................................................................................... 17.3 Operation .......................................................................................................................... 555 555 556 556 557 Section 18 ROM .................................................................................................................. 559 18.1 Features............................................................................................................................. 559 18.2 Overview........................................................................................................................... 560 18.2.1 Block Diagram..................................................................................................... 560 18.2.2 Mode Transitions ................................................................................................. 560 18.2.3 On-Board Programming Modes........................................................................... 563 18.2.4 Flash Memory Emulation in RAM ...................................................................... 565 18.2.5 Differences between Boot Mode and User Program Mode ................................. 566 18.2.6 Block Configuration ............................................................................................ 567 18.3 Pin Configuration.............................................................................................................. 568 18.4 Register Configuration...................................................................................................... 568 18.5 Register Descriptions ........................................................................................................ 569 18.5.1 Flash Memory Control Register 1 (FLMCR1)..................................................... 569 18.5.2 Flash Memory Control Register 2 (FLMCR2)..................................................... 571 18.5.3 Erase Block Register 1 (EBR1) ........................................................................... 574 18.5.4 Erase Block Register 2 (EBR2) ........................................................................... 575 18.5.5 RAM Control Register (RAMCR) ....................................................................... 576 18.6 On-Board Programming Modes........................................................................................ 577 18.6.1 Boot Mode ........................................................................................................... 578 18.6.2 User Program Mode............................................................................................. 583 18.7 Programming/Erasing Flash Memory ............................................................................... 585 18.7.1 Program Mode ..................................................................................................... 587 18.7.2 Program-Verify Mode.......................................................................................... 588 18.7.3 Notes on Program/Program-Verify Procedure..................................................... 588 18.7.4 Erase Mode .......................................................................................................... 592 18.7.5 Erase-Verify Mode .............................................................................................. 592 18.8 Protection .......................................................................................................................... 594 Rev. 2.0, 03/01, page xvi of 20 18.8.1 Hardware Protection ............................................................................................ 18.8.2 Software Protection.............................................................................................. 18.8.3 Error Protection.................................................................................................... 18.8.4 NMI Input Disable Conditions............................................................................. 18.9 Flash Memory Emulation in RAM ................................................................................... 18.10 Flash Memory PROM Mode............................................................................................. 18.10.1 Socket Adapters and Memory Map ..................................................................... 18.10.2 Notes on Use of PROM Mode ............................................................................. 18.11 Notes on Flash Memory Programming/Erasing................................................................ 594 596 597 599 600 602 602 603 604 Section 19 Clock Pulse Generator .................................................................................. 609 19.1 Overview........................................................................................................................... 19.1.1 Block Diagram..................................................................................................... 19.2 Oscillator Circuit............................................................................................................... 19.2.1 Connecting a Crystal Resonator........................................................................... 19.2.2 External Clock Input............................................................................................ 19.3 Duty Adjustment Circuit................................................................................................... 19.4 Prescalers .......................................................................................................................... 19.5 Frequency Divider ............................................................................................................ 19.5.1 Register Configuration......................................................................................... 19.5.2 Division Control Register (DIVCR) .................................................................... 19.5.3 Usage Notes ......................................................................................................... 609 610 611 611 613 615 615 615 616 616 617 Section 20 Power-Down State ......................................................................................... 619 20.1 Overview........................................................................................................................... 619 20.2 Register Configuration...................................................................................................... 621 20.2.1 System Control Register (SYSCR) ...................................................................... 621 20.2.2 Module Standby Control Register (MSTCR) ...................................................... 623 20.3 Sleep Mode ....................................................................................................................... 625 20.3.1 Transition to Sleep Mode..................................................................................... 625 20.3.2 Exit from Sleep Mode.......................................................................................... 625 20.4 Software Standby Mode.................................................................................................... 626 20.4.1 Transition to Software Standby Mode ................................................................. 626 20.4.2 Exit from Software Standby Mode ...................................................................... 626 20.4.3 Selection of Waiting Time for Exit from Software Standby Mode ..................... 627 20.4.4 Sample Application of Software Standby Mode.................................................. 629 20.4.5 Note...................................................................................................................... 629 20.5 Hardware Standby Mode .................................................................................................. 630 20.5.1 Transition to Hardware Standby Mode................................................................ 630 20.5.2 Exit from Hardware Standby Mode ..................................................................... 630 20.5.3 Timing for Hardware Standby Mode ................................................................... 630 20.6 Module Standby Function................................................................................................. 631 20.6.1 Module Standby Timing ...................................................................................... 631 Rev. 2.0, 03/01, page xvii of 20 20.6.2 Read/Write in Module Standby ........................................................................... 631 20.6.3 Usage Notes ......................................................................................................... 632 20.7 System Clock Output Disabling Function......................................................................... 633 Section 21 Electrical Characteristics (Preliminary)................................................... 635 21.1 Absolute Maximum Ratings ............................................................................................. 21.2 Electrical Characteristics................................................................................................... 21.2.1 DC Characteristics ............................................................................................... 21.2.2 AC Characteristics ............................................................................................... 21.2.3 A/D Conversion Characteristics........................................................................... 21.2.4 D/A Conversion Characteristics........................................................................... 21.2.5 Flash Memory Characteristics ............................................................................. 21.3 Operational Timing........................................................................................................... 21.3.1 Bus Timing .......................................................................................................... 21.3.2 Refresh Controller Bus Timing............................................................................ 21.3.3 Control Signal Timing ......................................................................................... 21.3.4 Clock Timing ....................................................................................................... 21.3.5 TPC and I/O Port Timing..................................................................................... 21.3.6 ITU Timing .......................................................................................................... 21.3.7 SCI Input/Output Timing..................................................................................... 21.3.8 DMAC Timing..................................................................................................... 635 636 636 643 649 650 651 652 652 656 661 663 663 664 665 666 Appendix A A.1 A.2 A.3 Instruction Set............................................................................................. 667 Instruction List .................................................................................................................. 667 Operation Code Map......................................................................................................... 682 Number of States Required for Execution ........................................................................ 685 Appendix B B.1 B.2 Internal I/O Register ................................................................................. 695 Addresses .......................................................................................................................... 695 Function ............................................................................................................................ 703 I/O Port Block Diagrams......................................................................... 784 784 785 786 787 788 789 793 794 797 801 805 Appendix C C.1 C.2 C.3 C.4 C.5 C.6 C.7 C.8 C.9 C.10 C.11 Port 1 Block Diagram ....................................................................................................... Port 2 Block Diagram ....................................................................................................... Port 3 Block Diagram ....................................................................................................... Port 4 Block Diagram ....................................................................................................... Port 5 Block Diagram ....................................................................................................... Port 6 Block Diagrams...................................................................................................... Port 7 Block Diagrams...................................................................................................... Port 8 Block Diagrams...................................................................................................... Port 9 Block Diagrams...................................................................................................... Port A Block Diagrams ..................................................................................................... Port B Block Diagrams ..................................................................................................... Rev. 2.0, 03/01, page xviii of 20 Appendix D D.1 D.2 Pin States...................................................................................................... 809 Port States in Each Mode .................................................................................................. 809 Pin States at Reset ............................................................................................................. 812 Timing of Transition to and Recovery from Hardware Standby Mode............................................................................................. 815 Appendix E E.1 E.2 Timing of Transition to Hardware Standby Mode ............................................................ 815 Timing of Recovery from Hardware Standby Mode......................................................... 815 Appendix F Appendix G Appendix H Product Code Lineup................................................................................ 816 Package Dimensions................................................................................. 817 Differences from H8/3048F-ZTAT...................................................... 819 Rev. 2.0, 03/01, page xix of 20 Rev. 2.0, 03/01, page xx of 20 Section 1 Overview 1.1 Overview The H8/3052F is a series of microcontrollers (MCUs) that integrate system supporting functions together with an H8/300H CPU core having an original Hitachi architecture. The H8/300H CPU has a 32-bit internal architecture with sixteen 16-bit general registers, and a concise, optimized instruction set designed for speed. It can address a 16-Mbyte linear address space. Its instruction set is upward-compatible at the object-code level with the H8/300 CPU, enabling easy porting of software from the H8/300 Series. The on-chip system supporting functions include ROM, RAM, a 16-bit integrated timer unit (ITU), a programmable timing pattern controller (TPC), a watchdog timer (WDT), a serial communication interface (SCI), an A/D converter, a D/A converter, I/O ports, a direct memory access controller (DMAC), a refresh controller, and other facilities. The H8/3052F has 512 kbytes of ROM and 8 kbytes of RAM. Seven MCU operating modes offer a choice of data bus width and address space size. The modes (modes 1 to 7) include one single-chip mode and six expanded modes. The H8/3052F has an F-ZTATTM* version with on-chip flash memory that can be programmed on-board. Table 1.1 summarizes the features of the H8/3052F. Note: * F-ZTAT (Flexible-Zero Turn Around Time) is a trademark of Hitachi, Ltd. Rev. 2.0, 03/01 page 1 of 822 Table 1.1 Feature CPU Features Description Upward-compatible with the H8/300 CPU at the object-code level * General-register machine Sixteen 16-bit general registers (also usable as + eight 16-bit registers or eight 32-bit registers) * High-speed operation Maximum clock rate: 25 MHz Add/subtract: 80 ns Multiply/divide: 560 ns 16-Mbyte address space * Instruction features 8/16/32-bit data transfer, arithmetic, and logic instructions Signed and unsigned multiply instructions (8 bits x 8 bits, 16 bits x 16 bits) Signed and unsigned divide instructions (16 bits / 8 bits, 32 bits / 16 bits) Bit accumulator function Bit manipulation instructions with register-indirect specification of bit positions Memory * * Flash memory: 512 kbytes RAM: 8 kbytes Seven external interrupt pins: NMI, ,540 to#,545 30 internal interrupts Three selectable interrupt priority levels Interrupt controller * * * Rev. 2.0, 03/01, page 2 of 822 Feature Bus controller Description * * * * * * Address space can be partitioned into eight areas, with independent bus specifications in each area Chip select output available for areas 0 to 7 8-bit access or 16-bit access selectable for each area Two-state or three-state access selectable for each area Selection of four wait modes Bus arbitration function DRAM refresh Directly connectable to 16-bit-wide DRAM CAS-before-RAS refresh Self-refresh mode selectable * * Pseudo-static RAM refresh Self-refresh mode selectable Usable as an interval timer Short address mode Maximum four channels available Selection of I/O mode, idle mode, or repeat mode Can be activated by compare match/input capture A interrupts from ITU channels 0 to 3, transmit-data-empty and receive-data-full interrupts from SCI channel 0, or external requests * Full address mode Maximum two channels available Selection of normal mode or block transfer mode Can be activated by compare match/input capture A interrupts from ITU channels 0 to 3, external requests, or auto-request Refresh controller * DMA controller (DMAC) * Rev. 2.0, 03/01 page 3 of 822 Feature 16-bit integrated timer unit (ITU) Description * * * * * * * * * * Five 16-bit timer channels, capable of processing up to 12 pulse outputs or 10 pulse inputs 16-bit timer counter (channels 0 to 4) Two multiplexed output compare/input capture pins (channels 0 to 4) Operation can be synchronized (channels 0 to 4) PWM mode available (channels 0 to 4) Phase counting mode available (channel 2) Buffering available (channels 3 and 4) Reset-synchronized PWM mode available (channels 3 and 4) Complementary PWM mode available (channels 3 and 4) DMAC can be activated by compare match/input capture A interrupts (channels 0 to 3) Maximum 16-bit pulse output, using ITU as time base Up to four 4-bit pulse output groups (or one 16-bit group, or two 8-bit groups) Non-overlap mode available Output data can be transferred by DMAC Reset signal can be generated by overflow Usable as an interval timer Selection of asynchronous or synchronous mode Full duplex: can transmit and receive simultaneously On-chip baud-rate generator Smart card interface functions added (SCI0 only) Resolution: 10 bits Eight channels, with selection of single or scan mode Variable analog conversion voltage range Sample-and-hold function A/D conversion can be externally triggered Programmable timing pattern controller (TPC) * * * * Watchdog timer (WDT), 1 channel Serial communication interface (SCI), 2 channels * * * * * * A/D converter * * * * * Rev. 2.0, 03/01, page 4 of 822 Feature D/A converter Description * * * Resolution: 8 bits Two channels D/A outputs can be sustained in software standby mode 70 input/output pins 9 input-only pins Seven MCU operating modes Address Space 1 Mbyte 1 Mbyte 16 Mbytes 16 Mbytes 1 Mbyte 16 Mbytes 1 Mbyte Address Pins A19 to A0 A19 to A0 A23 to A0 A23 to A0 A19 to A0 A23 to A0 -- Initial Bus Width 8 bits 16 bits 8 bits 16 bits 8 bits 8 bits -- Max. Bus Width 16 bits 16 bits 16 bits 16 bits 16 bits 16 bits -- I/O ports * * Operating modes * Mode Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 * On-chip ROM is disabled in modes 1 to 4 Sleep mode Software standby mode Hardware standby mode Module standby function Programmable system clock frequency division On-chip clock pulse generator Product Code 5V version HD64F3052F HD64F3052TE Package(Hitachi Package Code) 100-pin QFP (FP-100B) 100-pin TQFP (TFP-100B) 100-pin QFP (FP-100B) 100-pin TQFP (TFP-100B) 100-pin QFP (FP-100B) Power-down state * * * * * Other features Product lineup * Product Type H8/3052F-ZTAT H8/3052F-ZTAT B mask version 5V version HD64F3052BF HD64F3052BTE 3V version HD64F3052BVF HD64F3052BVTE 100-pin TQFP (TFP-100B) Rev. 2.0, 03/01 page 5 of 822 1.2 Block Diagram Figure 1.1 shows an internal block diagram. VCL/VCC P37/D15 P36/D14 P35/D13 P34/D12 P33/D11 P32/D10 P31/D9 P30/D8 P47/D7 P46/D6 P45/D5 P44/D4 P43/D3 P42/D2 P41/D1 VCC VCC VSS VSS VSS VSS VSS VSS Port 3 Address bus Port 4 P53/A19 Port 5 Port 2 Port 1 Port 9 Port 7 MD2 MD1 MD0 EXTAL XTAL STBY RES FWE NMI P66/LWR P65/HWR P64/RD P63/AS P62/BACK P61/BREQ P60/WAIT RAM P84/CS0 P82/CS2/IRQ2 P81/CS3/IRQ1 P80/RFSH/IRQ0 Interrupt controller Data bus (upper) Data bus (lower) P40/D0 P52/A18 P51/A17 P50/A16 Clock pulse generator P27/A15 H8/300H CPU P26/A14 P25/A13 P24/A12 P23/A11 P22/A10 P21/A9 P20/A8 P17/A7 P16/A6 P15/A5 Refresh controller P14/A4 P13/A3 P12/A2 P11/A1 Watchdog timer (WDT) P10/A0 DMA controller (DMAC) Port 6 ROM (flash memory) Port 8 P83/CS1/IRQ3 16-bit integrated timer unit (ITU) Serial communication interface (SCI) x 2 channels P95/SCK1/IRQ5 P94/SCK0/IRQ4 P93/RxD1 P92/RxD0 P91/TxD1 P90/TxD0 Programmable timing pattern controller (TPC) A/D converter D/A converter Port B Port A PA6/TP6/TIOCA2/A21/CS4 PA5/TP5/TIOCB1/A22/CS5 PA4/TP4/TIOCA1/A23/CS6 PA1/TP1/TEND1/TCLKB PA3/TP3/TIOCB0/TCLKD PB7/TP15/DREQ1/ADTRG PA2/TP2/TIOCA0/TCLKC PA0/TP0/TEND0/TCLKA PB6/TP14/DREQ0/CS7 PB5/TP13/TOCXB4 PB4/TP12/TOCXA4 PB3/TP11/TIOCB4 PB2/TP10/TIOCA4 PB1/TP9/TIOCB3 PB0/TP8/TIOCA3 PA7/TP7/TIOCB2/A20 P77/AN7/DA1 P76/AN6/DA0 Bus controller P75/AN5 P74/AN4 P73/AN3 P72/AN2 P71/AN1 Figure 1.1 Block Diagram Rev. 2.0, 03/01, page 6 of 822 P70/AN0 AVCC AVSS VREF 1.3 1.3.1 Pin Description Pin Arrangement Figure 1.2 shows the pin arrangement of the H8/3052F. P61 /BREQ P62 /BACK P60 /WAIT P65 /HWR P66 /LWR P53 /A 19 P52 /A 18 P51 /A 17 P50 /A 16 53 P27 /A 15 52 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 AVCC VREF P70 /AN 0 P71 /AN 1 P72 /AN 2 P73 /AN 3 P74 /AN 4 P75 /AN 5 P76 /AN6 /DA 0 P77 /AN7 /DA 1 AVSS P80 /RFSH/IRQ 0 P8 1 /CS 3 /IRQ 1 P8 2 /CS 2 /IRQ 2 P8 3 /CS 1 /IRQ 3 P84 /CS 0 VSS PA 0 /TP0 /TEND 0 /TCLKA PA1 /TP1 /TEND1 /TCLKB PA2 /TP2 /TIOCA 0/TCLKC PA3 /TP3 /TIOCB0 /TCLKD PA4 /TP4 /TIOCA1 /A23 /CS6 PA5 /TP5 /TIOCB1 /A22 /CS5 PA 6/TP 6 /TIOCA 2/A 21/CS4 PA 7 /TP7 /TIOCB 2 /A 20 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 Top view (FP-100B, TFP-100B) 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 P26 /A 14 P64 /RD P63 /AS EXTAL STBY XTAL RES MD2 MD1 MD0 VCC NMI VSS VSS o A13/P2 5 A12/P2 4 A11/P2 3 A10/P2 2 A 9 /P2 1 A 8 /P2 0 V SS A 7 /P17 A 6 /P16 A 5 /P15 A 4 /P14 A 3 /P13 A 2 /P12 A 1 /P11 A 0 /P10 V CC D15/P3 7 D14/P3 6 D13/P3 5 D12/P3 4 D11/P3 3 D10/P3 2 D9 /P31 D8 /P30 D7 /P47 10 11 12 13 14 15 16 17 18 19 20 21 22 VSS 23 D4 /P4 4 VCL/VCC* TIOCA3 /TP 8 /PB 0 TIOCB3 /TP 9 /PB 1 TIOCA4 /TP10 /PB 2 TIOCB4 /TP11 /PB 3 TOCXA4 /TP12 /PB 4 TOCXB4 /TP13 /PB 5 CS7/DREQ 0 /TP14 /PB 6 ADTRG/DREQ 1 /TP15 /PB 7 VSS TxD0 /P9 0 TxD1 /P9 1 RxD0 /P9 2 RxD1 /P9 3 IRQ 4/SCK0 /P9 4 IRQ 5/SCK1 /P9 5 D0 /P4 0 D1 /P4 1 D2 /P4 2 D3 /P4 3 D5 /P4 5 1 0.1 F (Preliminary) Note: * This pin functions as the VCL pin during 5 V operation and as the VCC pin during 3 V operation. An external capacitor must be connected to the VCL pin. Figure 1.2 Pin Arrangement (FP-100B or TFP-100B, Top View) Rev. 2.0, 03/01 page 7 of 822 D6 /P4 6 FWE 24 25 1 2 3 4 5 6 7 8 9 1.3.2 Pin Assignments in Each Mode Table 1.2 lists the pin assignments in each mode. Table 1.2 Pin Assignments in Each Mode (FP-100B or TFP-100B) Pin Name Pin No. Mode 1 1 2 3 4 5 6 7 8 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FEW VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 2 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 3 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 4 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 5 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 6 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40/ &67 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 Mode 7 VCL(VCC)* PB0/TP8/ TIOCA3 PB1/TP9/ TIOCB3 PB2/TP10/ TIOCA4 PB3/TP11/ TIOCB4 PB4/TP12/ TOCXA4 PB5/TP13/ TOCXB4 PB6/TP14/ '5(40 PB7/TP15/ '5(41/ $'75* FWE VSS P90/TxD0 P91/TxD1 P92/RxD0 P93/RxD1 P94/SCK0/ ,544 P95/SCK1/ ,545 1 9 10 11 12 13 14 15 16 17 Rev. 2.0, 03/01, page 8 of 822 Pin Name Pin No. Mode 1 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* P46/D6* 2 2 2 Mode 2 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* P46/D6* 3 3 3 Mode 3 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* P46/D6* 2 2 2 Mode 4 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* P46/D6* 3 3 3 Mode 5 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* P46/D6* 2 2 2 Mode 6 P40/D0* P41/D1* P42/D2* P43/D3* VSS P44/D4* P45/D5* 2 2 2 Mode 7 P40 P41 P42 P43 VSS P44 P45 P46 P47 P30 P31 P32 P33 P34 P35 P36 P37 VCC P10 P11 P12 P13 P14 P15 P16 P17 VSS P20 P21 2 3 2 3 2 2 2 3 2 3 2 2 2 3 2 3 2 2 2 3 2 3 2 2 P46/D6* 2 P47/D7* 2 P47/D7* 3 P47/D7* 2 P47/D7* 3 P47/D7* 2 P47/D7* D8 D9 D10 D11 D12 D13 D14 D15 VCC A0 A1 A2 A3 A4 A5 A6 A7 VSS A8 A9 D8 D9 D10 D11 D12 D13 D14 D15 VCC A0 A1 A2 A3 A4 A5 A6 A7 VSS A8 A9 D8 D9 D10 D11 D12 D13 D14 D15 VCC A0 A1 A2 A3 A4 A5 A6 A7 VSS A8 A9 D8 D9 D10 D11 D12 D13 D14 D15 VCC A0 A1 A2 A3 A4 A5 A6 A7 VSS A8 A9 D8 D9 D10 D11 D12 D13 D14 D15 VCC P10/A0 P11/A1 P12/A2 P13/A3 P14/A4 P15/A5 P16/A6 P17/A7 VSS P20/A8 P21/A9 D8 D9 D10 D11 D12 D13 D14 D15 VCC P10/A0 P11/A1 P12/A2 P13/A3 P14/A4 P15/A5 P16/A6 P17/A7 VSS P20/A8 P21/A9 Rev. 2.0, 03/01 page 9 of 822 Pin Name Pin No. Mode 1 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 2 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 3 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 4 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 5 P22/A10 P23/A11 P24/A12 P25/A13 P26/A14 P27/A15 P50/A16 P51/A17 P52/A18 P53/A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 6 P22/A10 P23/A11 P24/A12 P25/A13 P26/A14 P27/A15 P50/A16 P51/A17 P52/A18 P53/A19 VSS P60/:$,7 P61/%5(4 P62/%$&. 67%< 5(6 NMI VSS EXTAL XTAL VCC $6 5' +:5 /:5 MD0 MD1 MD2 Mode 7 P22 P23 P24 P25 P26 P27 P50 P51 P52 P53 VSS P60 P61 P62 67%< 5(6 NMI VSS EXTAL XTAL VCC P63 P64 P65 P66 MD0 MD1 MD2 Rev. 2.0, 03/01, page 10 of 822 Pin Name Pin No. Mode 1 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS P80/5)6+/ ,540 P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC Mode 2 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS Mode 3 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS Mode 4 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS Mode 5 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS Mode 6 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS Mode 7 AVCC VREF P70/AN0 P71/AN1 P72/AN2 P73/AN3 P74/AN4 P75/AN5 P76/AN6/ DA0 P77/AN7/ DA1 AVSS P80/5)6+/ P80/5)6+/ P80/5)6+/ ,540 ,540 ,540 P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC P80/5)6+/ P80/5)6+/ P80/,540 ,540 ,540 P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC P81/&63/ ,541 P82/&62/ ,542 P83/&61/ ,543 P84/&60 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC P81/,541 P82/,542 P83/,543 P84 VSS PA0/TP0/ 7(1'0/ TCLKA PA1/TP1/ 7(1'1/ TCLKB PA2/TP2/ TIOCA0/ TCLKC 94 95 Rev. 2.0, 03/01 page 11 of 822 Pin Name Pin No. Mode 1 96 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ &66 PA5/TP5/ TIOCB1/ &65 PA6/TP6/ TIOCA2/ &64 PA7/TP7/ TIOCB2 Mode 2 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ &66 PA5/TP5/ TIOCB1/ &65 PA6/TP6/ TIOCA2/ &64 PA7/TP7/ TIOCB2 Mode 3 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ &66 PA5/TP5/ TIOCB1/ &65 PA6/TP6/ TIOCA2/ &64 A20 Mode 4 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ &66 PA5/TP5/ TIOCB1/ &65 PA6/TP6/ TIOCA2/ &64 A20 Mode 5 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ &66 PA5/TP5/ TIOCB1/ &65 PA6/TP6/ TIOCA2/ &64 PA7/TP7/ TIOCB2 Mode 6 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1/ A23/&66 PA5/TP5/ TIOCB1/ A22/&65 PA6/TP6/ TIOCA2/ A21/&64 A20 Mode 7 PA3/TP3/ TIOCB0/ TCLKD PA4/TP4/ TIOCA1 PA5/TP5/ TIOCB1 PA6/TP6/ TIOCA2 PA7/TP7/ TIOCB2 97 98 99 100 Notes: 1. This pin functions as the VCL pin during 5 V operation and as the VCC pin during 3 V operation. An external capacitor must be connected when this pin functions as the VCL pin. 2. In modes 1, 3, 5, and 6 the P40 to P47 functions of pins P40/D0 to P47/D7 are selected after a reset, but they can be changed by software. 3. In modes 2 and 4 the D0 to D7 functions of pins P40/D0 to P47/D7 are selected after a reset, but they can be changed by software. Rev. 2.0, 03/01, page 12 of 822 1.3.3 Pin Functions Table 1.3 summarizes the pin functions. Table 1.3 Type Power Pin Functions Symbol VCC Pin No. 35, 68 I/O Input Name and Function Power: For connection to the power supply. Connect all VCC pins to the system power supply. Ground: For connection to ground (0 V). Connect all VSS pins to the 0-V system power supply. Connect an external capacitor between this pin and GND (0 V). VCL 0.1 F VSS 11, 22, 44, 57, 65, 92 1* Input VCL Input Clock XTAL 67 Input For connection to a crystal resonator. For examples of crystal resonator and external clock input, see section 19, Clock Pulse Generator. For connection to a crystal resonator or input of an external clock signal. For examples of crystal resonator and external clock input, see section 19, Clock Pulse Generator. System clock: Supplies the system clock to external devices. Mode 2 to mode 0: For setting the operating mode, as follows. Inputs at these pins must not be changed during operation. MD2 0 0 0 0 1 1 1 1 MD1 0 0 1 1 0 0 1 1 MD0 0 1 0 1 0 1 0 1 Operating Mode -- Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 EXTAL 66 Input Operating mode MD2 to MD0 control 61 75 to 73 Output Input Rev. 2.0, 03/01 page 13 of 822 Type System control Symbol 5(6 FWE 67%< %5(4 %$&. Pin No. 63 10 62 59 60 I/O Input Input Input Input Output Name and Function Reset input: When driven low, this pin resets the chip Flash write enable: Allows program mode setting. Standby: When driven low, this pin forces a transition to hardware standby mode Bus request: Used by an external bus master to request the bus right Bus request acknowledge: Indicates that the bus has been granted to an external bus master Nonmaskable interrupt: Requests a nonmaskable interrupt Interrupt request 5 to 0: Maskable interrupt request pins Address bus: Outputs address signals Interrupts NMI ,545 to ,540 64 17, 16, 90 to 87 97 to 100, 56 to 45, 43 to 36 34 to 23, 21 to 18 8, 97 to 99, 88 to 91 69 70 71 Input Input Output Address bus A23 to A0 Data bus Bus control D15 to D0 &67 to &60 $6 5' +:5 Input/ output Output Output Output Output Data bus: Bidirectional data bus Chip select: Select signals for areas 7 to 0 Address strobe: Goes low to indicate valid address output on the address bus Read: Goes low to indicate reading from the external address space High write: Goes low to indicate writing to the external address space; indicates valid data on the upper data bus (D15 to D8). Low write: Goes low to indicate writing to the external address space; indicates valid data on the lower data bus (D7 to D0). Wait: Requests insertion of wait states in bus cycles during access to the external address space /:5 72 Output :$,7 58 Input Rev. 2.0, 03/01, page 14 of 822 Type Refresh controller Symbol 5)6+ &63 5' Pin No. 87 88 70 I/O Output Output Output Name and Function Refresh: Indicates a refresh cycle Row address strobe 5$6: Row address 5$6 strobe signal for DRAM connected to area 3 Column address strobe &$6 Column &$6: address strobe signal for DRAM connected to area 3; used with 2:( DRAM. Write enable :( Write enable signal for :(: DRAM connected to area 3; used with 2&$6#DRAM. +:5 71 Output Upper write 8: Write enable signal for 8:: DRAM connected to area 3; used with 2:( DRAM. Upper column address strobe 8&$6 8&$6: Column address strobe signal for DRAM connected to area 3; used with 2&$6 DRAM. /:5 72 Output Lower write /: Write enable signal for /:: DRAM connected to area 3; used with 2:( DRAM. Lower column address strobe /&$6 /&$6: Column address strobe signal for DRAM connected to area 3; used with 2&$6 DRAM. DMA controller (DMAC) '5(41, '5(40 7(1'1, 7(1'0 9, 8 94, 93 Input Output DMA request 1 and 0: DMAC activation requests Transfer end 1 and 0: These signals indicate that the DMAC has ended a data transfer Clock input D to A: External clock inputs Input capture/output compare A4 to A0: GRA4 to GRA0 output compare or input capture, or PWM output Input capture/output compare B4 to B0: GRB4 to GRB0 output compare or input capture, or PWM output Output compare XA4: PWM output Output compare XB4: PWM output 16-bit integrated TCLKD to timer unit (ITU) TCLKA TIOCA4 to TIOCA0 TIOCB4 to TIOCB0 TOCXA4 TOCXB4 96 to 93 4, 2, 99, 97, 95 5, 3, 100, 98, 96 6 7 Input Input/ output Input/ output Output Output Rev. 2.0, 03/01 page 15 of 822 Type Symbol Pin No. 9 to 2, 100 to 93 13, 12 15, 14 I/O Output Name and Function TPC output 15 to 0: Pulse output Programmable TP15 to TP0 timing pattern controller (TPC) Serial communication interface (SCI) TxD1, TxD0 RxD1, RxD0 Output Input Input/ output Input Input Output Input Transmit data (channels 0 and 1): SCI data output Receive data (channels 0 and 1): SCI data input Serial clock (channels 0 and 1): SCI clock input/output Analog 7 to 0: Analog input pins A/D trigger: External trigger input for starting A/D conversion Analog output: Analog output from the D/A converter Power supply pin for the A/D and D/A converters. Connect to the system power supply (+5 V) when not using the A/D and D/A converters. Ground pin for the A/D and D/A converters. Connect to system ground (0 V). Reference voltage input pin for the A/D and D/A converters. Connect to the system power supply (+5 V) when not using the A/D and D/A converters. Port 1: Eight input/output pins. The direction of each pin can be selected in the port 1 data direction register (P1DDR). Port 2: Eight input/output pins. The direction of each pin can be selected in the port 2 data direction register (P2DDR). Port 3: Eight input/output pins. The direction of each pin can be selected in the port 3 data direction register (P3DDR). Port 4: Eight input/output pins. The direction of each pin can be selected in the port 4 data direction register (P4DDR). SCK1, SCK0 17, 16 A/D converter AN7 to AN0 $'75* D/A converter A/D and D/A converters DA1, DA0 AVCC 85 to 78 9 85, 84 76 AVSS VREF 86 77 Input Input I/O ports P17 to P10 43 to 36 Input/ output Input/ output Input/ output Input/ output P27 to P20 52 to 45 P37 to P30 34 to 27 P47 to P40 26 to 23, 21 to 18 Rev. 2.0, 03/01, page 16 of 822 Type I/O ports Symbol P53 to P50 Pin No. 56 to 53 I/O Input/ output Input/ output Input Input/ output Input/ output Input/ output Input/ output Name and Function Port 5: Four input/output pins. The direction of each pin can be selected in the port 5 data direction register (P5DDR). Port 6: Seven input/output pins. The direction of each pin can be selected in the port 6 data direction register (P6DDR). Port 7: Eight input pins Port 8: Five input/output pins. The direction of each pin can be selected in the port 8 data direction register (P8DDR). Port 9: Six input/output pins. The direction of each pin can be selected in the port 9 data direction register (P9DDR). Port A: Eight input/output pins. The direction of each pin can be selected in the port A data direction register (PADDR). Port B: Eight input/output pins. The direction of each pin can be selected in the port B data direction register (PBDDR). P66 to P60 72 to 69, 60 to 58 85 to 78 91 to 87 P77 to P70 P84 to P80 P95 to P90 17 to 12 PA7 to PA0 100 to 93 PB7 to PB0 9 to 2 Notes: This pin functions as the VCL pin during 5 V operation and as the VCC pin (should be connected to the system power supply) during 3 V operation. Rev. 2.0, 03/01 page 17 of 822 Rev. 2.0, 03/01, page 18 of 822 Section 2 CPU 2.1 Overview The H8/300H CPU is a high-speed central processing unit with an internal 32-bit architecture that is upward-compatible with the H8/300 CPU. The H8/300H CPU has sixteen 16-bit general registers, can address a 16-Mbyte linear address space, and is ideal for realtime control. 2.1.1 Features The H8/300H CPU has the following features. * Upward compatibility with H8/300 CPU Can execute H8/300 Series object programs * General-register architecture Sixteen 16-bit general registers (also usable as sixteen 8-bit registers or eight 32-bit registers) * Sixty-two basic instructions 8/16/32-bit data transfer and arithmetic and logic instructions Multiply and divide instructions Powerful bit-manipulation instructions * Eight addressing modes Register direct [Rn] Register indirect [@ERn] Register indirect with displacement [@(d:16, ERn) or @(d:24, ERn)] Register indirect with post-increment or pre-decrement [@ERn+ or @-ERn] Absolute address [@aa:8, @aa:16, or @aa:24] Immediate [#xx:8, #xx:16, or #xx:32] Program-counter relative [@(d:8, PC) or @(d:16, PC)] Memory indirect [@@aa:8] * 16-Mbyte linear address space * High-speed operation All frequently-used instructions execute in two to four states 25 MHz Maximum clock frequency: 8/16/32-bit register-register add/subtract: 80 ns 560 ns 8 x 8-bit register-register multiply: 16 / 8-bit register-register divide: 16 x 16-bit register-register multiply: 32 / 16-bit register-register divide: 560 ns 0.88 s 0.88 s Rev. 2.0, 03/01, page 19 of 822 * Two CPU operating modes Normal mode (not available in the H8/3052F) Advanced mode * Low-power mode Transition to power-down state by SLEEP instruction 2.1.2 Differences from H8/300 CPU In comparison to the H8/300 CPU, the H8/300H has the following enhancements. * More general registers Eight 16-bit registers have been added. * Expanded address space Advanced mode supports a maximum 16-Mbyte address space. Normal mode supports the same 64-kbyte address space as the H8/300 CPU. (Normal mode is not available in the H8/3052F.) * Enhanced addressing The addressing modes have been enhanced to make effective use of the 16-Mbyte address space. * Enhanced instructions Data transfer, arithmetic, and logic instructions can operate on 32-bit data. Signed multiply/divide instructions and other instructions have been added. Rev. 2.0, 03/01, page 20 of 822 2.2 CPU Operating Modes The H8/300H CPU has two operating modes: normal and advanced. Normal mode supports a maximum 64-kbyte address space. Advanced mode supports up to 16 Mbytes. The H8/3052F can be used only in advanced mode. (Information from this point on will apply to advanced mode unless otherwise stated.) Normal mode Maximum 64 kbytes, program and data areas combined CPU operating modes Maximum 16 Mbytes, program and data areas combined Advanced mode Figure 2.1 CPU Operating Modes Rev. 2.0, 03/01, page 21 of 822 2.3 Address Space The maximum address space of the H8/300H CPU is 16 Mbytes. The H8/3052F has various operating modes (MCU modes), some providing a 1-Mbyte address space, the others supporting the full 16 Mbytes. Figure 2.2 shows the address ranges of the H8/3052F. For further details see section 3.6, Memory Map in Each Operating Mode. The 1-Mbyte operating modes use 20-bit addressing. The upper 4 bits of effective addresses are ignored. H'00000 H'000000 H'FFFFF H'FFFFFF a. 1-Mbyte modes b. 16-Mbyte modes Figure 2.2 Memory Map Rev. 2.0, 03/01, page 22 of 822 2.4 2.4.1 Register Configuration Overview The H8/300H CPU has the internal registers shown in figure 2.3. There are two types of registers: general registers and control registers. General Registers (ERn) 15 ER0 ER1 ER2 ER3 ER4 ER5 ER6 ER7 Control Registers (CR) 23 PC 76543210 CCR I UI H U N Z V C Legend SP: Stack pointer PC: Program counter CCR: Condition code register Interrupt mask bit I: User bit or interrupt mask bit UI: Half-carry flag H: User bit U: Negative flag N: Zero flag Z: Overflow flag V: Carry flag C: 0 E0 E1 E2 E3 E4 E5 E6 E7 (SP) 07 R0H R1H R2H R3H R4H R5H R6H R7H 07 R0L R1L R2L R3L R4L R5L R6L R7L 0 Figure 2.3 CPU Internal Registers Rev. 2.0, 03/01, page 23 of 822 2.4.2 General Registers The H8/300H CPU has eight 32-bit general registers. These general registers are all functionally alike and can be used without distinction between data registers and address registers. When a general register is used as a data register, it can be accessed as a 32-bit, 16-bit, or 8-bit register. When the general registers are used as 32-bit registers or as address registers, they are designated by the letters ER (ER0 to ER7). The ER registers divide into 16-bit general registers designated by the letters E (E0 to E7) and R (R0 to R7). These registers are functionally equivalent, providing a maximum sixteen 16-bit registers. The E registers (E0 to E7) are also referred to as extended registers. The R registers divide into 8-bit general registers designated by the letters RH (R0H to R7H) and RL (R0L to R7L). These registers are functionally equivalent, providing a maximum sixteen 8-bit registers. Figure 2.4 illustrates the usage of the general registers. The usage of each register can be selected independently. * Address registers * 32-bit registers * 16-bit registers E registers (extended registers) E0 to E7 * 8-bit registers ER registers ER0 to ER7 R registers R0 to R7 RH registers R0H to R7H RL registers R0L to R7L Figure 2.4 Usage of General Registers Rev. 2.0, 03/01, page 24 of 822 General register ER7 has the function of stack pointer (SP) in addition to its general-register function, and is used implicitly in exception handling and subroutine calls. Figure 2.5 shows the stack. Free area SP (ER7) Stack area Figure 2.5 Stack 2.4.3 Control Registers The control registers are the 24-bit program counter (PC) and the 8-bit condition code register (CCR). Program Counter (PC): This 24-bit counter indicates the address of the next instruction the CPU will execute. The length of all CPU instructions is 2 bytes (one word) or a multiple of 2 bytes, so the least significant PC bit is ignored. When an instruction is fetched, the least significant PC bit is regarded as 0. Condition Code Register (CCR): This 8-bit register contains internal CPU status information, including the interrupt mask bit (I) and half-carry (H), negative (N), zero (Z), overflow (V), and carry (C) flags. * Bit 7--Interrupt Mask Bit (I) Masks interrupts other than NMI when set to 1. NMI is accepted regardless of the I bit setting. The I bit is set to 1 at the start of an exception-handling sequence. * Bit 6--User Bit or Interrupt Mask Bit (UI) Can be written and read by software using the LDC, STC, ANDC, ORC, and XORC instructions. This bit can also be used as an interrupt mask bit. For details see section 5, Interrupt Controller. * Bit 5--Half-Carry Flag (H) When the ADD.B, ADDX.B, SUB.B, SUBX.B, CMP.B, or NEG.B instruction is executed, this flag is set to 1 if there is a carry or borrow at bit 3, and cleared to 0 otherwise. When the ADD.W, SUB.W, CMP.W, or NEG.W instruction is executed, the H flag is set to 1 if there is a carry or borrow at bit 11, and cleared to 0 otherwise. When the ADD.L, SUB.L, CMP.L, or Rev. 2.0, 03/01, page 25 of 822 NEG.L instruction is executed, the H flag is set to 1 if there is a carry or borrow at bit 27, and cleared to 0 otherwise. * Bit 4--User Bit (U) Can be written and read by software using the LDC, STC, ANDC, ORC, and XORC instructions. * Bit 3--Negative Flag (N) Indicates the most significant bit (sign bit) of data. * Bit 2--Zero Flag (Z) Set to 1 to indicate zero data, and cleared to 0 to indicate non-zero data. * Bit 1--Overflow Flag (V) Set to 1 when an arithmetic overflow occurs, and cleared to 0 at other times. * Bit 0--Carry Flag (C) Set to 1 when a carry occurs, and cleared to 0 otherwise. Used by: Add instructions, to indicate a carry Subtract instructions, to indicate a borrow Shift and rotate instructions, to store the value shifted out of the end bit The carry flag is also used as a bit accumulator by bit manipulation instructions. Some instructions leave flag bits unchanged. Operations can be performed on CCR by the LDC, STC, ANDC, ORC, and XORC instructions. The N, Z, V, and C flags are used by conditional branch (Bcc) instructions. For the action of each instruction on the flag bits, see appendix A.1, Instruction List. For the I and UI bits, see section 5, Interrupt Controller. 2.4.4 Initial CPU Register Values In reset exception handling, PC is initialized to a value loaded from the vector table, and the I bit in CCR is set to 1. The other CCR bits and the general registers are not initialized. The initial value of the stack pointer (ER7) is undefined. The stack pointer must therefore be initialized by an MOV.L instruction executed immediately after a reset. Rev. 2.0, 03/01, page 26 of 822 2.5 Data Formats The H8/300H CPU can process 1-bit, 4-bit (BCD), 8-bit (byte), 16-bit (word), and 32-bit (longword) data. Bit-manipulation instructions operate on 1-bit data by accessing bit n (n = 0, 1, 2, ..., 7) of byte operand data. The DAA and DAS decimal-adjust instructions treat byte data as two digits of 4-bit BCD data. 2.5.1 General Register Data Formats Figure 2.6 shows the data formats in general registers. Data Type General Register Data Format 7 0 Don't care 7 0 1-bit data RnH 76543210 1-bit data RnL 7 Don't care 43 0 76543210 4-bit BCD data RnH Upper digit Lower digit Don't care 7 43 0 4-bit BCD data RnL 7 Don't care 0 Upper digit Lower digit Byte data RnH MSB LSB 7 Don't care 0 LSB Byte data RnL Don't care MSB Figure 2.6 General Register Data Formats (1) Rev. 2.0, 03/01, page 27 of 822 Data Type General Register Data Format 15 0 LSB Word data Rn MSB 15 0 LSB 16 15 0 LSB Word data En MSB 31 Longword data ERn MSB Legend ERn: General register En: General register E Rn: General register R RnH: General register RH RnL: General register RL MSB: Most significant bit LSB: Least significant bit Figure 2.6 General Register Data Formats (2) Rev. 2.0, 03/01, page 28 of 822 2.5.2 Memory Data Formats Figure 2.7 shows the data formats on memory. The H8/300H CPU can access word data and longword data on memory, but word or longword data must begin at an even address. If an attempt is made to access word or longword data at an odd address, no address error occurs but the least significant bit of the address is regarded as 0, so the access starts at the preceding address. This also applies to instruction fetches. Data Type Address Data Format 7 1-bit data Byte data Word data Address L Address L Address 2M Address 2M + 1 Address 2N Longword data Address 2N + 1 Address 2N + 2 Address 2N + 3 MSB 0 6 5 4 3 2 1 0 LSB 7 MSB MSB LSB LSB Figure 2.7 Memory Data Formats When ER7 (SP) is used as an address register to access the stack, the operand size should be word size or longword size. Rev. 2.0, 03/01, page 29 of 822 2.6 2.6.1 Instruction Set Instruction Set Overview The H8/300H CPU has 62 types of instructions, which are classified in table 2.1. Table 2.1 Function Data transfer Arithmetic operations Instruction Classification Instruction 1 1 2 2 MOV, PUSH* , POP* , MOVTPE* , MOVFPE* Types 3 18 ADD, SUB, ADDX, SUBX, INC, DEC, ADDS, SUBS, DAA, DAS, MULXU, MULXS, DIVXU, DIVXS, CMP, NEG, EXTS, EXTU AND, OR, XOR, NOT SHAL, SHAR, SHLL, SHLR, ROTL, ROTR, ROTXL, ROTXR BSET, BCLR, BNOT, BTST, BAND, BIAND, BOR, BIOR, BXOR, BIXOR, BLD, BILD, BST, BIST Bcc* , JMP, BSR, JSR, RTS TRAPA, RTE, SLEEP, LDC, STC, ANDC, ORC, XORC, NOP EEPMOV 3 Logic operations Shift operations Bit manipulation Branch System control Block data transfer 4 8 14 5 9 1 Total 62 types Notes: 1. POP.W Rn is identical to MOV.W @SP+, Rn. PUSH.W Rn is identical to MOV.W Rn, @-SP. POP.L ERn is identical to MOV.L @SP+, Rn. PUSH.L ERn is identical to MOV.L Rn, @-SP. 2. Not available in the H8/3052F. 3. Bcc is a generic branching instruction. Rev. 2.0, 03/01, page 30 of 822 2.6.2 Instructions and Addressing Modes Table 2.2 indicates the instructions available in the H8/300H CPU. Table 2.2 Instructions and Addressing Modes Addressing Modes @(d:16,ERn) @ERn+/@-ERn @(d:24,ERn) @(d:8,PC) Function Instruction @ERn @(d:16,PC) @@aa:8 @aa:16 @aa:24 @aa:8 #xx Rn Data transfer MOV POP, PUSH MOVFPE,* MOVTPE* BWL -- -- BWL WL B -- -- -- -- -- -- BWL -- -- -- -- -- -- -- -- -- B -- B -- -- BWL -- -- BWL BWL B L BWL B BW BWL WL BWL BWL BWL B -- -- -- -- -- -- B B -- -- -- BWL -- -- -- -- -- -- -- -- -- -- -- -- -- -- B -- -- -- -- -- W W -- -- -- BWL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- W W -- -- -- BWL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- W W -- -- -- BWL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- W W -- -- -- B -- -- -- -- -- -- -- -- -- -- -- -- -- -- B -- -- -- -- -- -- -- -- -- -- -- BWL -- B -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- W W -- -- -- BWL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- WL -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Arithmetic operations ADD, CMP SUB ADDX, SUBX ADDS, SUBS INC, DEC DAA, DAS MULXU, MULXS, DIVXU, DIVXS NEG EXTU, EXTS Logic operations AND, OR, XOR NOT Shift instructions Bit manipulation Branch Bcc, BSR JMP, JSR RTS System control TRAPA RTE SLEEP LDC STC ANDC, ORC, XORC NOP Block data transfer -- -- -- -- W W -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- BW -- -- -- Legend B: Byte W: Word L: Longword Note: * Not available in the H8/3052F. Rev. 2.0, 03/01, page 31 of 822 -- -- 2.6.3 Tables of Instructions Classified by Function Tables 2.3 to 2.10 summarize the instructions in each functional category. The operation notation used in these tables is defined next. Operation Notation Rd Rs Rn ERn (EAd) (EAs) CCR N Z V C PC SP #IMM disp + - x / :3/:8/:16/:24 General register (destination)* General register (source)* General register* General register (32-bit register or address register) Destination operand Source operand Condition code register N (negative) flag of CCR Z (zero) flag of CCR V (overflow) flag of CCR C (carry) flag of CCR Program counter Stack pointer Immediate data Displacement Addition Subtraction Multiplication Division AND logical OR logical Exclusive OR logical Move NOT (logical complement) 3-, 8-, 16-, or 24-bit length Note: * General registers include 8-bit registers (R0H to R7H, R0L to R7L), 16-bit registers (R0 to R7, E0 to E7), and 32-bit data or address registers (ER0 to ER7). Rev. 2.0, 03/01, page 32 of 822 Table 2.3 Instruction MOV Data Transfer Instructions Size* B/W/L Function (EAs) Rd, Rs (EAd) Moves data between two general registers or between a general register and memory, or moves immediate data to a general register. MOVFPE MOVTPE POP B B W/L (EAs) Rd Cannot be used in the H8/3052F. Rs (EAs) Cannot be used in the H8/3052F. @SP+ Rn Pops a general register from the stack. POP.W Rn is identical to MOV.W @SP+, Rn. Similarly, POP.L ERn is identical to MOV.L @SP+, ERn. PUSH W/L Rn @-SP Pushes a general register onto the stack. PUSH.W Rn is identical to MOV.W Rn, @-SP. Similarly, PUSH.L ERn is identical to MOV.L ERn, @-SP. Note: * Size refers to the operand size. B: Byte W: Word L: Longword Rev. 2.0, 03/01, page 33 of 822 Table 2.4 Instruction ADD, SUB Arithmetic Operation Instructions Size* B/W/L Function Rd Rs Rd, Rd #IMM Rd Performs addition or subtraction on data in two general registers, or on immediate data and data in a general register. (Immediate byte data cannot be subtracted from data in a general register. Use the SUBX or ADD instruction.) ADDX, SUBX B Rd Rs C Rd, Rd #IMM C Rd Performs addition or subtraction with carry or borrow on data in two general registers, or on immediate data and data in a general register. INC, DEC B/W/L Rd 1 Rd, Rd 2 Rd Increments or decrements a general register by 1 or 2. (Byte operands can be incremented or decremented by 1 only.) ADDS, SUBS L Rd 1 Rd, Rd 2 Rd, Rd 4 Rd Adds or subtracts the value 1, 2, or 4 to or from data in a 32-bit register. DAA, DAS B Rd decimal adjust Rd Decimal-adjusts an addition or subtraction result in a general register by referring to CCR to produce 4-bit BCD data. MULXU B/W Rd x Rs Rd Performs unsigned multiplication on data in two general registers: either 8 bits x 8 bits 16 bits or 16 bits x 16 bits 32 bits. MULXS B/W Rd x Rs Rd Performs signed multiplication on data in two general registers: either 8 bits x 8 bits 16 bits or 16 bits x 16 bits 32 bits. Rev. 2.0, 03/01, page 34 of 822 Instruction DIVXU Size* B/W Function Rd / Rs Rd Performs unsigned division on data in two general registers: either 16 bits / 8 bits 8-bit quotient and 8-bit remainder or 32 bits / 16 bits 16-bit quotient and 16-bit remainder. DIVXS B/W Rd / Rs Rd Performs signed division on data in two general registers: either 16 bits / 8 bits 8-bit quotient and 8-bit remainder, or 32 bits / 16 bits 16-bit quotient and 16-bit remainder. CMP B/W/L Rd - Rs, Rd - #IMM Compares data in a general register with data in another general register or with immediate data, and sets CCR according to the result. NEG B/W/L 0 - Rd Rd Takes the two's complement (arithmetic complement) of data in a general register. EXTS W/L Rd (sign extension) Rd Extends byte data in the lower 8 bits of a 16-bit register to word data, or extends word data in the lower 16 bits of a 32-bit register to longword data, by extending the sign bit. EXTU W/L Rd (zero extension) Rd Extends byte data in the lower 8 bits of a 16-bit register to word data, or extends word data in the lower 16 bits of a 32-bit register to longword data, by padding with zeros. Note: * Size refers to the operand size. B: Byte W: Word L: Longword Rev. 2.0, 03/01, page 35 of 822 Table 2.5 Instruction AND Logic Operation Instructions Size* B/W/L Function Rd Rs Rd, Rd #IMM Rd Performs a logical AND operation on a general register and another general register or immediate data. OR B/W/L Rd Rs Rd, Rd #IMM Rd Performs a logical OR operation on a general register and another general register or immediate data. XOR B/W/L Rd Rs Rd, Rd #IMM Rd Performs a logical exclusive OR operation on a general register and another general register or immediate data. NOT B/W/L Rd Rd Takes the one's complement of general register contents. Note: * Size refers to the operand size. B: Byte W: Word L: Longword Table 2.6 Instruction SHAL, SHAR SHLL, SHLR ROTL, ROTR ROTXL, ROTXR Shift Instructions Size* B/W/L B/W/L B/W/L B/W/L Function Rd (shift) Rd Performs an arithmetic shift on general register contents. Rd (shift) Rd Performs a logical shift on general register contents. Rd (rotate) Rd Rotates general register contents. Rd (rotate) Rd Rotates general register contents through the carry bit. Note: * Size refers to the operand size. B: Byte W: Word L: Longword Rev. 2.0, 03/01, page 36 of 822 Table 2.7 Instruction BSET Bit Manipulation Instructions Size* B Function 1 ( of ) Sets a specified bit in a general register or memory operand to 1. The bit number is specified by 3-bit immediate data or the lower 3 bits of a general register. BCLR B 0 ( of ) Clears a specified bit in a general register or memory operand to 0. The bit number is specified by 3-bit immediate data or the lower 3 bits of a general register. BNOT B ( of ) ( of ) Inverts a specified bit in a general register or memory operand. The bit number is specified by 3-bit immediate data or the lower 3 bits of a general register. BTST B ( of ) Z Tests a specified bit in a general register or memory operand and sets or clears the Z flag accordingly. The bit number is specified by 3-bit immediate data or the lower 3 bits of a general register. BAND B C ( of ) C ANDs the carry flag with a specified bit in a general register or memory operand and stores the result in the carry flag. BIAND B C [ ( of )] C ANDs the carry flag with the inverse of a specified bit in a general register or memory operand and stores the result in the carry flag. The bit number is specified by 3-bit immediate data. Rev. 2.0, 03/01, page 37 of 822 Instruction BOR Size* B Function C ( of ) C ORs the carry flag with a specified bit in a general register or memory operand and stores the result in the carry flag. BIOR B C [ ( of )] C ORs the carry flag with the inverse of a specified bit in a general register or memory operand and stores the result in the carry flag. The bit number is specified by 3-bit immediate data. BXOR B C ( of ) C Exclusive-ORs the carry flag with a specified bit in a general register or memory operand and stores the result in the carry flag. BIXOR B C [ ( of )] C Exclusive-ORs the carry flag with the inverse of a specified bit in a general register or memory operand and stores the result in the carry flag. The bit number is specified by 3-bit immediate data. BLD B ( of ) C Transfers a specified bit in a general register or memory operand to the carry flag. BILD B ( of ) C Transfers the inverse of a specified bit in a general register or memory operand to the carry flag. The bit number is specified by 3-bit immediate data. BST B C ( of ) Transfers the carry flag value to a specified bit in a general register or memory operand. BIST B C ( of ) Transfers the inverse of the carry flag value to a specified bit in a general register or memory operand. The bit number is specified by 3-bit immediate data. Note: * Size refers to the operand size. B: Byte Rev. 2.0, 03/01, page 38 of 822 Table 2.8 Instruction Bcc Branching Instructions Size -- Function Branches to a specified address if a specified condition is true. The branching conditions are listed below. Mnemonic BRA (BT) BRN (BF) BHI BLS Bcc (BHS) BCS (BLO) BNE BEQ BVC BVS BPL BMI BGE BLT BGT BLE Description Always (true) Never (false) High Low or same Carry clear (high or same) Carry set (low) Not equal Equal Overflow clear Overflow set Plus Minus Greater or equal Less than Greater than Less or equal Condition Always Never CZ=0 CZ=1 C=0 C=1 Z=0 Z=1 V=0 V=1 N=0 N=1 NV=0 NV=1 Z (N V) = 0 Z (N V) = 1 JMP BSR JSR RTS -- -- -- -- Branches unconditionally to a specified address Branches to a subroutine at a specified address Branches to a subroutine at a specified address Returns from a subroutine Rev. 2.0, 03/01, page 39 of 822 Table 2.9 Instruction TRAPA RTE SLEEP LDC System Control Instructions Size* -- -- -- B/W Function Starts trap-instruction exception handling Returns from an exception-handling routine Causes a transition to the power-down state (EAs) CCR Moves the source operand contents to the condition code register. The condition code register size is one byte, but in transfer from memory, data is read by word access. STC B/W CCR (EAd) Transfers the CCR contents to a destination location. The condition code register size is one byte, but in transfer to memory, data is written by word access. ANDC ORC XORC B B B CCR #IMM CCR Logically ANDs the condition code register with immediate data. CCR #IMM CCR Logically ORs the condition code register with immediate data. CCR #IMM CCR Logically exclusive-ORs the condition code register with immediate data. NOP -- PC + 2 PC Only increments the program counter. Note: * Size refers to the operand size. B: Byte W: Word Rev. 2.0, 03/01, page 40 of 822 Table 2.10 Block Transfer Instruction Instruction EEPMOV.B Size -- Function if R4L 0 then repeat until else next; EEPMOV.W -- if R4 0 then repeat until else next; Transfers a data block according to parameters set in general registers R4L or R4, ER5, and ER6. R4L or R4: Size of block (bytes) ER5: Starting source address ER6: Starting destination address Execution of the next instruction begins as soon as the transfer is completed. @ER5+ @ER6+, R4 - 1 R4 R4 = 0 @ER5+ @ER6+, R4L - 1 R4L R4L = 0 Rev. 2.0, 03/01, page 41 of 822 2.6.4 Basic Instruction Formats The H8/300H instructions consist of 2-byte (1-word) units. An instruction consists of an operation field (OP field), a register field (r field), an effective address extension (EA field), and a condition field (cc). Operation Field: Indicates the function of the instruction, the addressing mode, and the operation to be carried out on the operand. The operation field always includes the first 4 bits of the instruction. Some instructions have two operation fields. Register Field: Specifies a general register. Address registers are specified by 3 bits, data registers by 3 bits or 4 bits. Some instructions have two register fields. Some have no register field. Effective Address Extension: Eight, 16, or 32 bits specifying immediate data, an absolute address, or a displacement. A 24-bit address or displacement is treated as 32-bit data in which the first 8 bits are 0 (H'00). Condition Field: Specifies the branching condition of Bcc instructions. Figure 2.8 shows examples of instruction formats. Operation field only op Operation field and register fields op rn rm ADD.B Rn, Rm, etc. NOP, RTS, etc. Operation field, register fields, and effective address extension op EA (disp) Operation field, effective address extension, and condition field op cc EA (disp) BRA d:8 rn rm MOV.B @(d:16, Rn), Rm Figure 2.8 Instruction Formats Rev. 2.0, 03/01, page 42 of 822 2.6.5 Notes on Use of Bit Manipulation Instructions The BSET, BCLR, BNOT, BST, and BIST instructions read a byte of data, modify a bit in the byte, then write the byte back. Care is required when these instructions are used to access registers with write-only bits, or to access ports. The BCLR instruction can be used to clear flags in the on-chip registers. In an interrupt-handling routine, for example, if it is known that the flag is set to 1, it is not necessary to read the flag ahead of time. Step 1 2 3 Read Bit manipulation Write Description Read data (byte unit) at the specified address Modify the specified bit in the read data Write the modified data (byte unit) to the specified address In the following example, a BCLR instruction is executed on the data direction register (DDR) of port 4. P47 and P46 are set as input pins, and are inputting low-level and high-level signals, respectively. P45 to P40 are set as output pins, and are in the low-level output state. In this example, the BCLR instruction is used to make P40 an input port. Before Execution of BCLR Instruction P47 Input/output DDR DR Input 0 1 P46 Input 0 0 P45 Output 1 0 P44 Output 1 0 P43 Output 1 0 P42 Output 1 0 P41 Output 1 0 P40 Output 1 0 Execution of BCLR Instruction BCLR #0, @P4DDR ; Execute BCLR instruction on DDR After Execution of BCLR Instruction P47 Input/output DDR DR Output 1 1 P46 Output 1 0 P45 Output 1 0 P44 Output 1 0 P43 Output 1 0 P42 Output 1 0 P41 Output 1 0 P40 Input 0 0 Rev. 2.0, 03/01, page 43 of 822 Explanation of BCLR Instruction To execute the BCLR instruction, the CPU begins by reading P4DDR. Since P4DDR is a writeonly register, it is read as H'FF, even though its true value is H'3F. Next the CPU clears bit 0 of the read data, changing the value to H'FE. Finally, the CPU writes this value (H'FE) back to DDR to complete the BCLR instruction. As a result, P40DDR is cleared to 0, making P40 an input pin. In addition, P47DDR and P46DDR are set to 1, making P47 and P46 output pins. The BCLR instruction can be used to clear flags in the internal I/O registers to 0. In an interrupthandling routine, for example, if it is known that the flag is set to 1, it is not necessary to read the flag ahead of time. 2.7 2.7.1 Addressing Modes and Effective Address Calculation Addressing Modes The H8/300H CPU supports the eight addressing modes listed in table 2.11. Each instruction uses a subset of these addressing modes. Arithmetic and logic instructions can use the register direct and immediate modes. Data transfer instructions can use all addressing modes except programcounter relative and memory indirect. Bit manipulation instructions use register direct, register indirect, or absolute (@aa:8) addressing mode to specify an operand, and register direct (BSET, BCLR, BNOT, and BTST instructions) or immediate (3-bit) addressing mode to specify a bit number in the operand. Table 2.11 Addressing Modes No. 1 2 3 4 Addressing Mode Register direct Register indirect Register indirect with displacement Register indirect with post-increment Register indirect with pre-decrement 5 6 7 8 Absolute address Immediate Program-counter relative Memory indirect Symbol Rn @ERn @(d:16, ERn)/@(d:24, ERn) @ERn+ @-ERn @aa:8/@aa:16/@aa:24 #xx:8/#xx:16/#xx:32 @(d:8, PC)/@(d:16, PC) @@aa:8 Rev. 2.0, 03/01, page 44 of 822 Register Direct--Rn: The register field of the instruction code specifies an 8-, 16-, or 32-bit register containing the operand. R0H to R7H and R0L to R7L can be specified as 8-bit registers. R0 to R7 and E0 to E7 can be specified as 16-bit registers. ER0 to ER7 can be specified as 32-bit registers. Register Indirect--@ERn: The register field of the instruction code specifies an address register (ERn), the lower 24 bits of which contain the address of the operand. Register Indirect with Displacement--@(d:16, ERn) or @(d:24, ERn): A 16-bit or 24-bit displacement contained in the instruction code is added to the contents of an address register (ERn) specified by the register field of the instruction, and the lower 24 bits of the sum specify the address of a memory operand. A 16-bit displacement is sign-extended when added. Register Indirect with Post-Increment or Pre-Decrement--@ERn+ or @-ERn: * Register indirect with post-increment--@ERn+ The register field of the instruction code specifies an address register (ERn) the lower 24 bits of which contain the address of a memory operand. After the operand is accessed, 1, 2, or 4 is added to the address register contents (32 bits) and the sum is stored in the address register. The value added is 1 for byte access, 2 for word access, or 4 for longword access. For word or longword access, the register value should be even. * Register indirect with pre-decrement--@-ERn The value 1, 2, or 4 is subtracted from an address register (ERn) specified by the register field in the instruction code, and the lower 24 bits of the result become the address of a memory operand. The result is also stored in the address register. The value subtracted is 1 for byte access, 2 for word access, or 4 for longword access. For word or longword access, the resulting register value should be even. Absolute Address--@aa:8, @aa:16, or @aa:24: The instruction code contains the absolute address of a memory operand. The absolute address may be 8 bits long (@aa:8), 16 bits long (@aa:16), or 24 bits long (@aa:24). For an 8-bit absolute address, the upper 16 bits are all assumed to be 1 (H'FFFF). For a 16-bit absolute address the upper 8 bits are a sign extension. A 24-bit absolute address can access the entire address space. Table 2.12 indicates the accessible address ranges. Rev. 2.0, 03/01, page 45 of 822 Table 2.12 Absolute Address Access Ranges Absolute Address 8 bits (@aa:8) 16 bits (@aa:16) 1-Mbyte Modes H'FFF00 to H'FFFFF (1048320 to 1048575) H'00000 to H'07FFF, H'F8000 to H'FFFFF (0 to 32767, 1015808 to 1048575) H'00000 to H'FFFFF (0 to 1048575) 16-Mbyte Modes H'FFFF00 to H'FFFFFF (16776960 to 16777215) H'000000 to H'007FFF, H'FF8000 to H'FFFFFF (0 to 32767, 16744448 to 16777215) H'000000 to H'FFFFFF (0 to 16777215) 24 bits (@aa:24) Immediate--#xx:8, #xx:16, or #xx:32: The instruction code contains 8-bit (#xx:8), 16-bit (#xx:16), or 32-bit (#xx:32) immediate data as an operand. The instruction codes of the ADDS, SUBS, INC, and DEC instructions contain immediate data implicitly. The instruction codes of some bit manipulation instructions contain 3-bit immediate data specifying a bit number. The TRAPA instruction code contains 2-bit immediate data specifying a vector address. Program-Counter Relative--@(d:8, PC) or @(d:16, PC): This mode is used in the Bcc and BSR instructions. An 8-bit or 16-bit displacement contained in the instruction code is signextended to 24 bits and added to the 24-bit PC contents to generate a 24-bit branch address. The PC value to which the displacement is added is the address of the first byte of the next instruction, so the possible branching range is -126 to +128 bytes (-63 to +64 words) or -32766 to +32768 bytes (-16383 to +16384 words) from the branch instruction. The resulting value should be an even number. Memory Indirect--@@aa:8: This mode can be used by the JMP and JSR instructions. The instruction code contains an 8-bit absolute address specifying a memory operand. This memory operand contains a branch address. The memory operand is accessed by longword access. The first byte of the memory operand is ignored, generating a 24-bit branch address. See figure 2.9. The upper bits of the 8-bit absolute address are assumed to be 0 (H'0000), so the address range is 0 to 255 (H'000000 to H'0000FF). Note that the first part of this range is also the exception vector area. For further details see section 5, Interrupt Controller. Rev. 2.0, 03/01, page 46 of 822 Specified by @aa:8 Reserved Branch address Figure 2.9 Memory-Indirect Branch Address Specification When a word-size or longword-size memory operand is specified, or when a branch address is specified, if the specified memory address is odd, the least significant bit is regarded as 0. The accessed data or instruction code therefore begins at the preceding address. See section 2.5.2, Memory Data Formats. 2.7.2 Effective Address Calculation Table 2.13 explains how an effective address is calculated in each addressing mode. In the 1-Mbyte operating modes the upper 4 bits of the calculated address are ignored in order to generate a 20-bit effective address. Rev. 2.0, 03/01, page 47 of 822 Table 2.13 Effective Address Calculation No. 1 Addressing Mode and Instruction Format Register direct (Rn) op rm rn Effective Address Calculation Effective Address Operand is general register contents 2 Register indirect (@ERn) 31 General register contents op r 0 23 0 3 Register indirect with displacement @(d:16, ERn)/@(d:24, ERn) 31 General register contents 23 op r disp 0 0 Sign extension disp 4 Register indirect with post-increment or pre-decrement Register indirect with post-increment @ERn+ 31 General register contents 0 23 0 op r 1, 2, or 4 Register indirect with pre-decrement @-ERn 31 General register contents 23 op r 1, 2, or 4 1 for a byte operand, 2 for a word operand, 4 for a longword operand 0 0 Rev. 2.0, 03/01, page 48 of 822 No. 5 Addressing Mode and Instruction Format Absolute address @aa:8 op abs Effective Address Calculation Effective Address 23 H'FFFF 87 0 @aa:16 op abs 23 16 15 Sign extension 0 @aa:24 op abs 23 0 6 Immediate #xx:8, #xx:16, or #xx:32 op IMM Operand is immediate data 7 Program-counter relative @(d:8, PC) or @(d:16, PC) 23 PC contents 0 23 0 Sign extension op disp disp Rev. 2.0, 03/01, page 49 of 822 No. 8 Addressing Mode and Instruction Format Memory indirect @@aa:8 * Normal mode op abs Effective Address Calculation Effective Address 23 H'0000 87 abs 0 15 0 23 16 15 0 Memory contents H'00 * Advanced mode op abs 23 H'0000 87 abs 0 31 Memory contents 0 23 0 Legend: r, rm, rn: Register field op: Operation field disp: Displacement IMM: Immediate data abs: Absolute address Rev. 2.0, 03/01, page 50 of 822 2.8 2.8.1 Processing States Overview The H8/300H CPU has five processing states: the program execution state, exception-handling state, power-down state, reset state, and bus-released state. The power-down state includes sleep mode, software standby mode, and hardware standby mode. Figure 2.10 classifies the processing states. Figure 2.12 indicates the state transitions. Processing states Program execution state The CPU executes program instructions in sequence Exception-handling state A transient state in which the CPU executes a hardware sequence (saving PC and CCR, fetching a vector, etc.) in response to a reset, interrupt, or other exception Bus-released state The external bus has been released in response to a bus request signal from a bus master other than the CPU Reset state The CPU and all on-chip supporting modules are initialized and halted Power-down state The CPU is halted to conserve power Sleep mode Software standby mode Hardware standby mode Figure 2.10 Processing States Rev. 2.0, 03/01, page 51 of 822 2.8.2 Program Execution State In this state the CPU executes program instructions in normal sequence. 2.8.3 Exception-Handling State The exception-handling state is a transient state that occurs when the CPU alters the normal program flow due to a reset, interrupt, or trap instruction. The CPU fetches a starting address from the exception vector table and branches to that address. In interrupt and trap exception handling the CPU references the stack pointer (ER7) and saves the program counter and condition code register. Types of Exception Handling and Their Priority: Exception handling is performed for resets, interrupts, and trap instructions. Table 2.14 indicates the types of exception handling and their priority. Trap instruction exceptions are accepted at all times in the program execution state. Table 2.14 Exception Handling Types and Priority Priority High Type of Exception Reset Interrupt Detection Timing Synchronized with clock End of instruction execution or end of exception handling* When TRAPA instruction is executed Start of Exception Handling Exception handling starts immediately when 5(6 changes from low to high When an interrupt is requested, exception handling starts at the end of the current instruction or current exception-handling sequence Exception handling starts when a trap (TRAPA) instruction is executed Low Trap instruction Note: * Interrupts are not detected at the end of the ANDC, ORC, XORC, and LDC instructions, or immediately after reset exception handling. Figure 2.11 classifies the exception sources. For further details about exception sources, vector numbers, and vector addresses, see section 4, Exception Handling, and section 5, Interrupt Controller. Rev. 2.0, 03/01, page 52 of 822 Reset External interrupts Exception sources Interrupt Internal interrupts (from on-chip supporting modules) Trap instruction Figure 2.11 Classification of Exception Sources End of bus release Bus request Program execution state End of bus release Bus request Exception Bus-released state End of exception handling Exception-handling state SLEEP instruction with SSBY = 0 Sleep mode Interrupt NMI, IRQ 0 , IRQ 1, or IRQ 2 interrupt SLEEP instruction with SSBY = 1 Software standby mode RES = High STBY = High, RES = Low Reset state*1 Hardware standby mode Power-down state *2 Notes: 1. From any state except hardware standby mode, a transition to the reset state occurs whenever RES goes low. 2. From any state, a transition to hardware standby mode occurs when STBY goes low. Figure 2.12 State Transitions Rev. 2.0, 03/01, page 53 of 822 2.8.4 Exception-Handling Sequences Reset Exception Handling: Reset exception handling has the highest priority. The reset state is entered when the 5(6 signal goes low. Reset exception handling starts after that, when 5(6 changes from low to high. When reset exception handling starts the CPU fetches a start address from the exception vector table and starts program execution from that address. All interrupts, including NMI, are disabled during the reset exception-handling sequence and immediately after it ends. Interrupt Exception Handling and Trap Instruction Exception Handling: When these exception-handling sequences begin, the CPU references the stack pointer (ER7) and pushes the program counter and condition code register on the stack. Next, if the UE bit in the system control register (SYSCR) is set to 1, the CPU sets the I bit in the condition code register to 1. If the UE bit is cleared to 0, the CPU sets both the I bit and the UI bit in the condition code register to 1. Then the CPU fetches a start address from the exception vector table and execution branches to that address. Figure 2.13 shows the stack after the exception-handling sequence. SP-4 SP-3 SP-2 SP-1 SP (ER7) Stack area SP (ER7) SP+1 SP+2 SP+3 SP+4 CCR PC Even address Before exception handling starts Legend CCR: Condition code register SP: Stack pointer Pushed on stack After exception handling ends Notes: 1. PC is the address of the first instruction executed after the return from the exception-handling routine. 2. Registers must be saved and restored by word access or longword access, starting at an even address. Figure 2.13 Stack Structure after Exception Handling Rev. 2.0, 03/01, page 54 of 822 2.8.5 Bus-Released State In this state the bus is released to a bus master other than the CPU, in response to a bus request. The bus masters other than the CPU are the DMA controller, the refresh controller, and an external bus master. While the bus is released, the CPU halts except for internal operations. Interrupt requests are not accepted. For details see section 6.3.7, Bus Arbiter Operation. 2.8.6 Reset State When the 5(6 input goes low all current processing stops and the CPU enters the reset state. The I bit in the condition code register is set to 1 by a reset. All interrupts are masked in the reset state. Reset exception handling starts when the 5(6 signal changes from low to high. The reset state can also be entered by a watchdog timer overflow. For details see section 12, Watchdog Timer. 2.8.7 Power-Down State In the power-down state the CPU stops operating to conserve power. There are three modes: sleep mode, software standby mode, and hardware standby mode. Sleep Mode: A transition to sleep mode is made if the SLEEP instruction is executed while the SSBY bit is cleared to 0 in the system control register (SYSCR). CPU operations stop immediately after execution of the SLEEP instruction, but the contents of CPU registers are retained. Software Standby Mode: A transition to software standby mode is made if the SLEEP instruction is executed while the SSBY bit is set to 1 in SYSCR. The CPU and clock halt and all on-chip supporting modules stop operating. The on-chip supporting modules are reset, but as long as a specified voltage is supplied the contents of CPU registers and on-chip RAM are retained. The I/O ports also remain in their existing states. Hardware Standby Mode: A transition to hardware standby mode is made when the 67%< input goes low. As in software standby mode, the CPU and all clocks halt and the on-chip supporting modules are reset, but as long as a specified voltage is supplied, on-chip RAM contents are retained. For further information see section 20, Power-Down State. Rev. 2.0, 03/01, page 55 of 822 2.9 2.9.1 Basic Operational Timing Overview The H8/300H CPU operates according to the system clock (). The interval from one rise of the system clock to the next rise is referred to as a "state." A memory cycle or bus cycle consists of two or three states. The CPU uses different methods to access on-chip memory, the on-chip supporting modules, and the external address space. Access to the external address space can be controlled by the bus controller. 2.9.2 On-Chip Memory Access Timing On-chip memory is accessed in two states. The data bus is 16 bits wide, permitting both byte and word access. Figure 2.14 shows the on-chip memory access cycle. Figure 2.15 indicates the pin states. Bus cycle T1 state Internal address bus Internal read signal Internal data bus (read access) Internal write signal Internal data bus (write access) Write data Read data Address T2 state Figure 2.14 On-Chip Memory Access Cycle Rev. 2.0, 03/01, page 56 of 822 T1 Address bus Address T2 AS , RD, HWR , LWR High High impedance D15 to D0 Figure 2.15 Pin States during On-Chip Memory Access 2.9.3 On-Chip Supporting Module Access Timing The on-chip supporting modules are accessed in three states. The data bus is 8 or 16 bits wide, depending on the register being accessed. Figure 2.16 shows the on-chip supporting module access timing. Figure 2.17 indicates the pin states. Bus cycle T1 state Address bus Internal read signal Internal data bus Address T2 state T3 state Read access Read data Internal write signal Write access Internal data bus Write data Figure 2.16 Access Cycle for On-Chip Supporting Modules Rev. 2.0, 03/01, page 57 of 822 T1 Address bus AS , RD, HWR , LWR T2 T3 Address High High impedance D15 to D0 Figure 2.17 Pin States during Access to On-Chip Supporting Modules 2.9.4 Access to External Address Space The external address space is divided into eight areas (areas 0 to 7). Bus-controller settings determine whether each area is accessed via an 8-bit or 16-bit bus, and whether it is accessed in two or three states. For details see section 6, Bus Controller. Rev. 2.0, 03/01, page 58 of 822 Section 3 MCU Operating Modes 3.1 3.1.1 Overview Operating Mode Selection The H8/3052F has seven operating modes (modes 1 to 7) that are selected by the mode pins (MD2 to MD0) as indicated in table 3.1. The input at these pins determines the size of the address space and the initial bus mode. Table 3.1 Operating Mode Selection Mode Pins Operating 3 Mode* -- Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 MD2 0 0 0 0 1 1 1 1 MD1 0 0 1 1 0 0 1 1 MD0 0 1 0 1 0 1 0 1 Address Space -- Expanded mode Expanded mode Expanded mode Expanded mode Expanded mode Expanded mode Single-chip advanced mode Description Initial Bus Mode* 1 On-Chip ROM -- Disabled Disabled Disabled Disabled Enabled Enabled Enabled On-Chip RAM -- Enabled* Enabled* Enabled* Enabled* Enabled* Enabled* Enabled 2 -- 8 bits 16 bits 8 bits 16 bits 8 bits 8 bits -- 2 2 2 2 2 Notes: 1. In modes 1 to 6, an 8-bit or 16-bit data bus can be selected on a per-area basis by settings made in the area bus width control register (ABWCR). For details see section 6, Bus Controller. 2. If the RAME bit in SYSCR is cleared to 0, these addresses become external addresses. 3. These are the operating modes when the FWE pin is at 0. For the operating modes when the FWE pin is at 1, see section 18, ROM. For the address space size there are two choices: 1 Mbyte or 16 Mbytes. The external data bus is either 8 or 16 bits wide depending on ABWCR settings. If 8-bit access is selected for all areas, the external data bus is 8 bits wide. For details see section 6, Bus Controller. Modes 1 to 4 are externally expanded modes that enable access to external memory and peripheral devices and disable access to the on-chip ROM. Modes 1 and 2 support a maximum address space of 1 Mbyte. Modes 3 and 4 support a maximum address space of 16 Mbytes. Rev. 2.0, 03/01, page 59 of 822 Modes 5 and 6 are externally expanded modes that enable access to external memory and peripheral devices and also enable access to the on-chip ROM. Mode 5 supports a maximum address space of 1 Mbyte. Mode 6 supports a maximum address space of 16 Mbytes. Mode 7 is a single-chip mode that operates using the on-chip ROM, RAM, and Internal I/O registers, and makes all I/O ports available. Mode 7 supports a 1-Mbyte address space. The H8/3052F can be used only in modes 1 to 7. The inputs at the mode pins must select one of these seven modes. The inputs at the mode pins must not be changed during operation. 3.1.2 Register Configuration The H8/3052F has a mode control register (MDCR) that indicates the inputs at the mode pins (MD2 to MD0), and a system control register (SYSCR). Table 3.2 summarizes these registers. Table 3.2 Address* H'FFF1 H'FFF2 Registers Name Mode control register System control register Abbreviation MDCR SYSCR R/W R R/W Initial Value Undetermined H'0B Note: * The lower 16 bits of the address are indicated. 3.2 Mode Control Register (MDCR) MDCR is an 8-bit read-only register that indicates the current operating mode of the H8/3052F. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 0 -- 4 -- 0 -- Reserved bits 3 -- 0 -- 2 MDS2 --* R 1 MDS1 --* R 0 MDS0 --* R Reserved bits Mode select 2 to 0 Bits indicating the current operating mode Note: * Determined by pins MD 2 to MD0 . Bits 7 and 6--Reserved: Read-only bits, always read as 1. Bits 5 to 3--Reserved: Read-only bits, always read as 0. Rev. 2.0, 03/01, page 60 of 822 Bits 2 to 0--Mode Select 2 to 0 (MDS2 to MDS0): These bits indicate the logic levels at pins MD2 to MD0 (the current operating mode). MDS2 to MDS0 correspond to MD2 to MD0. MDS2 to MDS0 are read-only bits. The mode pin (MD2 to MD0) levels are latched into these bits when MDCR is read. 3.3 System Control Register (SYSCR) SYSCR is an 8-bit register that controls the operation of the H8/3052F. Bit Initial value Read/Write 7 SSBY 0 R/W 6 STS2 0 R/W 5 STS1 0 R/W 4 STS0 0 R/W 3 UE 1 R/W 2 NMIEG 0 R/W 1 -- 1 -- 0 RAME 1 R/W RAM enable Enables or disables on-chip RAM Reserved bit NMI edge select Selects the valid edge of the NMI input User bit enable Selects whether to use the UI bit in CCR as a user bit or an interrupt mask bit Standby timer select 2 to 0 These bits select the waiting time at recovery from software standby mode Software standby Enables transition to software standby mode Bit 7--Software Standby (SSBY): Enables transition to software standby mode. (For further information about software standby mode see section 20, Power-Down State.) When software standby mode is exited by an external interrupt, this bit remains set to 1. To clear this bit, write 0. Bit 7: SSBY 0 1 Description SLEEP instruction causes transition to sleep mode SLEEP instruction causes transition to software standby mode (Initial value) Rev. 2.0, 03/01, page 61 of 822 Bits 6 to 4--Standby Timer Select (STS2 to STS0): These bits select the length of time the CPU and on-chip supporting modules wait for the internal clock oscillator to settle when software standby mode is exited by an external interrupt. When using a crystal oscillator, set these bits so that the waiting time will be at least 7 ms at the system clock rate. For further information about waiting time selection, see section 20.4.3, Selection of Waiting Time for Exit from Software Standby Mode. Bit 6: STS2 0 Bit 5: STS1 0 1 1 0 1 Bit 4: STS0 0 1 0 1 0 1 -- Description Waiting time = 8,192 states Waiting time = 16,384 states Waiting time = 32,768 states Waiting time = 65,536 states Waiting time = 131,072 states Waiting time = 1,024 states Illegal setting (Initial value) Bit 3--User Bit Enable (UE): Selects whether to use the UI bit in the condition code register as a user bit or an interrupt mask bit. Bit 3: UE 0 1 Description UI bit in CCR is used as an interrupt mask bit UI bit in CCR is used as a user bit (Initial value) Bit 2--NMI Edge Select (NMIEG): Selects the valid edge of the NMI input. Bit 2: NMIEG 0 1 Description An interrupt is requested at the falling edge of NMI An interrupt is requested at the rising edge of NMI (Initial value) Bit 1--Reserved: Read-only bit, always read as 1. Bit 0--RAM Enable (RAME): Enables or disables the on-chip RAM. The RAME bit is initialized by the rising edge of the 5(6 signal. It is not initialized in software standby mode. Bit 0: RAME 0 1 Description On-chip RAM is disabled On-chip RAM is enabled (Initial value) Rev. 2.0, 03/01, page 62 of 822 3.4 3.4.1 Operating Mode Descriptions Mode 1 Ports 1, 2, and 5 function as address pins A19 to A0, permitting access to a maximum 1-Mbyte address space. The initial bus mode after a reset is 8 bits, with 8-bit access to all areas. If at least one area is designated for 16-bit access in ABWCR, the bus mode switches to 16 bits. 3.4.2 Mode 2 Ports 1, 2, and 5 function as address pins A19 to A0, permitting access to a maximum 1-Mbyte address space. The initial bus mode after a reset is 16 bits, with 16-bit access to all areas. If all areas are designated for 8-bit access in ABWCR, the bus mode switches to 8 bits. 3.4.3 Mode 3 Ports 1, 2, and 5 and part of port A function as address pins A23 to A0, permitting access to a maximum 16-Mbyte address space. The initial bus mode after a reset is 8 bits, with 8-bit access to all areas. If at least one area is designated for 16-bit access in ABWCR, the bus mode switches to 16 bits. A23 to A21 are valid when 0 is written in bits 7 to 5 of the bus release control register (BRCR). (In this mode A20 is always used for address output.) 3.4.4 Mode 4 Ports 1, 2, and 5 and part of port A function as address pins A23 to A0, permitting access to a maximum 16-Mbyte address space. The initial bus mode after a reset is 16 bits, with 16-bit access to all areas. If all areas are designated for 8-bit access in ABWCR, the bus mode switches to 8 bits. A23 to A21 are valid when 0 is written in bits 7 to 5 of BRCR. (In this mode A20 is always used for address output.) 3.4.5 Mode 5 Ports 1, 2, and 5 can function as address pins A19 to A0, permitting access to a maximum 1-Mbyte address space, but following a reset they are input ports. To use ports 1, 2, and 5 as an address bus, the corresponding bits in their data direction registers (P1DDR, P2DDR, and P5DDR) must be set to 1. The initial bus mode after a reset is 8 bits, with 8-bit access to all areas. If at least one area is designated for 16-bit access in ABWCR, the bus mode switches to 16 bits. Rev. 2.0, 03/01, page 63 of 822 3.4.6 Mode 6 Ports 1, 2, and 5 and part of port A function as address pins A23 to A0, permitting access to a maximum 16-Mbyte address space, but following a reset they are input ports. To use ports 1, 2, and 5 as an address bus, the corresponding bits in their data direction registers (P1DDR, P2DDR, and P5DDR) must be set to 1. For A23 to A21 output, clear bits 7 to 5 of BRCR to 0. (In this mode A20 is always used for address output.) The initial bus mode after a reset is 8 bits, with 8-bit access to all areas. If at least one area is designated for 16-bit access in ABWCR, the bus mode switches to 16 bits. 3.4.7 Mode 7 This mode operates using the on-chip ROM, RAM, and registers. All I/O ports are available. Mode 7 supports a 1-Mbyte address space. 3.5 Pin Functions in Each Operating Mode The pin functions of ports 1 to 5 and port A vary depending on the operating mode. Table 3.3 indicates their functions in each operating mode. Table 3.3 Port Port 1 Port 2 Port 3 Port 4 Port 5 Port A Pin Functions in Each Mode Mode 2 A7 to A0 A15 to A8 D15 to D8 1 D7 to D0* Mode 1 A7 to A0 A15 to A8 D15 to D8 1 P47 to P40* Mode 3 A7 to A0 A15 to A8 D15 to D8 1 P47 to P40* Mode 4 A7 to A0 A15 to A8 D15 to D8 1 D7 to D0* Mode 5 P17 to P10* P27 to P20* D15 to D8 1 P47 to P40* 2 Mode 6 P17 to P10* P27 to P20* D15 to D8 1 P47 to P40* 2 Mode 7 P17 to P10 P27 to P20 P37 to P30 P47 to P40 P53 to P50 PA7 to PA4 2 2 A19 to A16 PA7 to PA4 A19 to A16 PA7 to PA4 A19 to A16 3 A19 to A16 3 P53 to P50* 2 P53 to P50* PA7 to PA5, 3 A20* 2 PA7 to PA5* , PA7 to PA5* , PA7 to PA4 A20 A20 Notes: 1. Initial state. The bus mode can be switched by settings in ABWCR. These pins function as P47 to P40 in 8-bit bus mode, and as D7 to D0 in 16-bit bus mode. 2. Initial state. These pins become address output pins when the corresponding bits in the data direction registers (P1DDR, P2DDR, P5DDR) are set to 1. 3. Initial state. A20 is always an address output pin. PA7 to PA5 are switched over to A23 to A21 output by writing 0 in bits 7 to 5 of BRCR. Rev. 2.0, 03/01, page 64 of 822 3.6 Memory Map in Each Operating Mode Figure 3.1 shows a memory map of the H8/3052F. The address space is divided into eight areas. The initial bus mode differs between modes 1 and 2, and also between modes 3 and 4. The address locations of the on-chip RAM and on-chip registers differ between the 1-Mbyte modes (modes 1, 2, 5, and 7) and 16-Mbyte modes (modes 3, 4, and 6). The address range specifiable by the CPU in the 8- and 16-bit absolute addressing modes (@aa:8 and @aa:16) also differs. Rev. 2.0, 03/01, page 65 of 822 Modes 1 and 2 (1-Mbyte expanded modes with on-chip ROM disabled) Modes 3 and 4 (16-Mbyte expanded modes with on-chip ROM disabled) Vector area Memory-indirect branch addresses 16-bit absolute addresses H'000FF H'0000FF H'07FFF H'007FFF H'1FFFF H'20000 H'3FFFF H'40000 H'5FFFF H'60000 External address space H'7FFFF H'80000 H'9FFFF H'A0000 H'BFFFF H'C0000 H'DFFFF H'E0000 Area 0 Area 1 Area 2 Area 3 Area 4 Area 5 Area 6 Area 7 H'7FFFFF H'800000 H'9FFFFF H'A00000 H'5FFFFF H'600000 External address space H'3FFFFF H'400000 H'1FFFFF H'200000 Area 0 Area 1 Area 2 Area 3 Area 4 H'F8000 16-bit absolute addresses H'FDF0F H'FDF10 Area 5 H'BFFFFF H'C00000 Area 6 H'DFFFFF H'E00000 Area 7 H'FFF00 H'FFF0F H'FFF10 H'FFF1B H'FFF1C H'FFFFF External address space Internal I/O registers 8-bit absolute addresses On-chip RAM * H'FF8000 H'FFFF00 H'FFFF0F H'FFFF10 H'FFFF1B H'FFFF1C H'FFFFFF Note: * External addresses can be accessed by disabling on-chip RAM. External address space Internal I/O registers Figure 3.1 H8/3052F Memory Map in Each Operating Mode Rev. 2.0, 03/01, page 66 of 822 8-bit absolute addresses On-chip RAM * 16-bit absolute addresses H'FFDF0F H'FFDF10 16-bit absolute addresses Vector area Memory-indirect branch addresses H'00000 H'000000 Mode 5 (1-Mbyte expanded mode with on-chip ROM enabled) Mode 6 (16-Mbyte expanded mode with on-chip ROM enabled) Mode 7 (single-chip advanced mode) H'00000 Memory-indirect branch addresses Memory-indirect branch addresses 16-bit absolute addresses 16-bit absolute addresses H'000FF On-chip ROM H'07FFF H'0000FF On-chip ROM H'007FFF H'000FF On-chip ROM H'07FFF H'7FFFF H'1FFFF H'20000 H'3FFFF H'40000 H'5FFFF H'60000 H'7FFFF H'80000 External address space H'9FFFF H'A0000 H'BFFFF H'C0000 H'DFFFF H'E0000 Area 0 Area 1 Area 2 Area 3 Area 4 Area 5 Area 6 Area 7 H'07FFFF H'080000 H'1FFFFF H'200000 H'3FFFFF H'400000 H'5FFFFF H'600000 H'7FFFFF H'800000 H'9FFFFF H'A00000 Area 0 Area 1 Area 2 External address space Area 3 Area 4 H'F8000 H'F8000 H'FDF10 H'FFF00 H'FFF0F 16-bit absolute addresses 8-bit absolute addresses H'FFF00 H'FFF0F H'FFF10 H'FFF1B H'FFF1C H'FFFFF External address space Internal I/O registers H'DFFFFF H'E00000 Area 6 Area 7 H'FF8000 H'FFF1C H'FFFFF Internal I/O registers H'FFFF00 H'FFFF0F H'FFFF10 H'FFFF1B H'FFFF1C H'FFFFFF External address space Internal I/O registers Note: * External addresses can be accessed by disabling on-chip RAM. Figure 3.1 H8/3052F Memory Map in Each Operating Mode (cont) 8-bit absolute addresses On-chip RAM * 16-bit absolute addresses H'FFDF0F H'FFDF10 Rev. 2.0, 03/01, page 67 of 822 8-bit absolute addresses On-chip RAM * H'BFFFFF H'C00000 Area 5 On-chip RAM 16-bit absolute addresses H'FDF0F H'FDF10 16-bit absolute addresses Vector area Vector area Vector area Memory-indirect branch addresses H'00000 H'000000 Rev. 2.0, 03/01, page 68 of 822 Section 4 Exception Handling 4.1 4.1.1 Overview Exception Handling Types and Priority As table 4.1 indicates, exception handling may be caused by a reset, trap instruction, or interrupt. Exception handling is prioritized as shown in table 4.1. If two or more exceptions occur simultaneously, they are accepted and processed in priority order. Trap instruction exceptions are accepted at all times in the program execution state. Table 4.1 Priority High Exception Types and Priority Exception Type Reset Interrupt Start of Exception Handling Starts immediately after a low-to-high transition at the 5(6 pin Interrupt requests are handled when execution of the current instruction or handling of the current exception is completed Started by execution of a trap instruction (TRAPA) Low Trap instruction (TRAPA) 4.1.2 Exception Handling Operation Exceptions originate from various sources. Trap instructions and interrupts are handled as follows. 1. The program counter (PC) and condition code register (CCR) are pushed onto the stack. 2. The CCR interrupt mask bit is set to 1. 3. A vector address corresponding to the exception source is generated, and program execution starts from the address indicated in that address. For a reset exception, steps 2 and 3 above are carried out. Rev. 2.0, 03/01, page 69 of 822 4.1.3 Exception Sources and Vector Table The exception sources are classified as shown in figure 4.1. Different vectors are assigned to different exception sources. Table 4.2 lists the exception sources and their vector addresses. * Reset External interrupts: NMI, IRQ 0 to IRQ5 Exception sources * Interrupts Internal interrupts: 30 interrupts from on-chip supporting modules * Trap instruction Figure 4.1 Exception Sources Rev. 2.0, 03/01, page 70 of 822 Table 4.2 Exception Vector Table Vector Number 0 1 2 3 4 5 6 Vector Address* H'0000 to H'0003 H'0004 to H'0007 H'0008 to H'000B H'000C to H'000F H'0010 to H'0013 H'0014 to H'0017 H'0018 to H'001B H'001C to H'001F H'0020 to H'0023 H'0024 to H'0027 H'0028 to H'002B H'002C to H'002F H'0030 to H'0033 H'0034 to H'0037 H'0038 to H'003B H'003C to H'003F H'0040 to H'0043 H'0044 to H'0047 H'0048 to H'004B H'004C to H'004F H'0050 to H'0053 to H'00F0 to H'00F3 1 Exception Source Reset Reserved for system use External interrupt (NMI) Trap instruction (4 sources) 7 8 9 10 11 External interrupt IRQ0 External interrupt IRQ1 External interrupt IRQ2 External interrupt IRQ3 External interrupt IRQ4 External interrupt IRQ5 Reserved for system use Internal interrupts* 12 13 14 15 16 17 18 19 20 to 60 2 Notes: 1. Lower 16 bits of the address. 2. For the internal interrupt vectors, see section 5.3.3, Interrupt Vector Table. Rev. 2.0, 03/01, page 71 of 822 4.2 4.2.1 Reset Overview A reset is the highest-priority exception. When the 5(6 pin goes low, all processing halts and the chip enters the reset state. A reset initializes the internal state of the CPU and the registers of the on-chip supporting modules. Reset exception handling begins when the 5(6 pin changes from low to high. The chip can also be reset by overflow of the watchdog timer. For details see section 12, Watchdog Timer. 4.2.2 Reset Sequence The chip enters the reset state when the 5(6 pin goes low. To ensure that the chip is reset, hold the 5(6 pin low for at least 20 ms at power-up. To reset the chip during operation, hold the 5(6 pin low for at least 20 system clock () cycles. See appendix D.2, Pin States at Reset, for the states of the pins in the reset state. When the 5(6 pin goes high after being held low for the necessary time, the chip starts reset exception handling as follows. * The internal state of the CPU and the registers of the on-chip supporting modules are initialized, and the I bit is set to 1 in CCR. * The contents of the reset vector address (H'0000 to H'0003) are read, and program execution starts from the address indicated in the vector address. Figure 4.2 shows the reset sequence in modes 1 and 3. Figure 4.3 shows the reset sequence in modes 2 and 4. Figure 4.4 shows the reset sequence in modes 5 to 7. Rev. 2.0, 03/01, page 72 of 822 Vector fetch Internal processing Prefetch of first program instruction Figure 4.2 Reset Sequence (Modes 1 and 3) Address bus (1) (3) (5) (7) (9) , D15 to D8 High (2) (4) (6) (8) (10) Rev. 2.0, 03/01, page 73 of 822 (1), (3), (5), (7) (2), (4), (6), (8) (9) (10) Address of reset vector: (1) = H'00000, (3) = H'00001, (5) = H'00002, (7) = H'00003 Start address (contents of reset vector) Start address First instruction of program Note: After a reset, the wait-state controller inserts three wait states in every bus cycle. Vector fetch Internal processing Prefetch of first program instruction Address bus (1) (3) (5) , D15 to D0 High (2) (4) (6) (1), (3) (2), (4) (5) (6) Address of reset vector: (1) = H'000000, (3) = H'000002 Start address (contents of reset vector) Start address First instruction of program Note: After a reset, the wait-state controller inserts three wait states in every bus cycle. Figure 4.3 Reset Sequence (Modes 2 and 4) Rev. 2.0, 03/01, page 74 of 822 Vector fetch Internal processing Prefetch of first program instruction Internal address bus Internal read signal Internal write signal Internal data bus (16 bits wide) (1) (3) (5) (2) (4) (6) (1), (3) (2), (4) (5) (6) Address of reset vector ((1) = H'000000, (2) = H'000002) Start address (contents of reset vector) Start address First instruction of program Figure 4.4 Reset Sequence (Modes 5 to 7) 4.2.3 Interrupts after Reset If an interrupt is accepted after a reset but before the stack pointer (SP) is initialized, PC and CCR will not be saved correctly, leading to a program crash. To prevent this, all interrupt requests, including NMI, are disabled immediately after a reset. The first instruction of the program is always executed immediately after the reset state ends. This instruction should initialize the stack pointer (example: MOV.L #xx:32, SP). Rev. 2.0, 03/01, page 75 of 822 4.3 Interrupts Interrupt exception handling can be requested by seven external sources (NMI, IRQ0 to IRQ5) and 30 internal sources in the on-chip supporting modules. Figure 4.5 classifies the interrupt sources and indicates the number of interrupts of each type. The on-chip supporting modules that can request interrupts are the watchdog timer (WDT), refresh controller, 16-bit integrated timer unit (ITU), DMA controller (DMAC), serial communication interface (SCI), and A/D converter. Each interrupt source has a separate vector address. NMI is the highest-priority interrupt and is always accepted. Interrupts are controlled by the interrupt controller. The interrupt controller can assign interrupts other than NMI to two priority levels, and arbitrate between simultaneous interrupts. Interrupt priorities are assigned in interrupt priority registers A and B (IPRA and IPRB) in the interrupt controller. For details on interrupts see section 5, Interrupt Controller. External interrupts Interrupts NMI (1) IRQ 0 to IRQ 5 (6) WDT *1 (1) Refresh controller *2 (1) ITU (15) DMAC (4) SCI (8) A/D converter (1) Internal interrupts Notes: Numbers in parentheses are the number of interrupt sources. 1. When the watchdog timer is used as an interval timer, it generates an interrupt request at every counter overflow. 2. When the refresh controller is used as an interval timer, it generates an interrupt request at compare match. Figure 4.5 Interrupt Sources and Number of Interrupts Rev. 2.0, 03/01, page 76 of 822 4.4 Trap Instruction Trap instruction exception handling starts when a TRAPA instruction is executed. If the UE bit is set to 1 in the system control register (SYSCR), the exception handling sequence sets the I bit to 1 in CCR. If the UE bit is 0, the I and UI bits are both set to 1. The TRAPA instruction fetches a start address from a vector table entry corresponding to a vector number from 0 to 3, which is specified in the instruction code. 4.5 Stack Status after Exception Handling Figure 4.6 shows the stack after completion of trap instruction exception handling and interrupt exception handling. SP-4 SP-3 SP-2 SP-1 SP (ER7) Stack area SP (ER7) SP+1 SP+2 SP+3 SP+4 CCR PC E PC H PC L Even address Before exception handling Pushed on stack After exception handling Legend PCE: Bits 23 to 16 of program counter (PC) PCH: Bits 15 to 8 of program counter (PC) PCL: Bits 7 to 0 of program counter (PC) CCR: Condition code register SP: Stack pointer Notes: 1. PC indicates the address of the first instruction that will be executed after return. 2. Register saving and restoration must be carried out in word or longword size at even addresses. Figure 4.6 Stack after Completion of Exception Handling Rev. 2.0, 03/01, page 77 of 822 4.6 Notes on Use of the Stack When accessing word data or longword data, the H8/3052F regards the lowest address bit as 0. The stack should always be accessed by word access or longword access, and the value of the stack pointer (SP, ER7) should always be kept even. Use the following instructions to save registers: PUSH.W Rn (or MOV.W Rn, @-SP) PUSH.L ERn (or MOV.L ERn, @-SP) Use the following instructions to restore registers: POP.W Rn POP.L ERn (or MOV.W @SP+, Rn) (or MOV.L @SP+, ERn) Setting SP to an odd value may lead to a malfunction. Figure 4.7 shows an example of what happens when the SP value is odd. CCR SP PC SP R1L H'FFFEFA H'FFFEFB PC H'FFFEFC H'FFFEFD H'FFFEFF SP TRAPA instruction executed MOV. B R1L, @-ER7 SP set to H'FFFEFF Legend CCR: Condition code register PC: Program counter R1L: General register R1L SP: Stack pointer Data saved above SP CCR contents lost Note: The diagram illustrates modes 3 and 4. Figure 4.7 Operation when SP Value is Odd Rev. 2.0, 03/01, page 78 of 822 Section 5 Interrupt Controller 5.1 5.1.1 Overview Features The interrupt controller has the following features: * Interrupt priority registers (IPRs) for setting interrupt priorities Interrupts other than NMI can be assigned to two priority levels on a source-by-source or module-by-module basis in interrupt priority registers A and B (IPRA and IPRB). * Three-level masking by the I and UI bits in the CPU condition code register (CCR) * Independent vector addresses All interrupts are independently vectored; the interrupt service routine does not have to identify the interrupt source. * Seven external interrupt pins NMI has the highest priority and is always accepted; either the rising or falling edge can be selected. For each of IRQ0 to IRQ5, falling edge or level sensing can be selected independently. Rev. 2.0, 03/01, page 79 of 822 5.1.2 Block Diagram Figure 5.1 shows a block diagram of the interrupt controller. CPU ISCR NMI input IRQ input OVF TME . . . . . . . ADI ADIE IRQ input section ISR Priority decision logic IER IPRA, IPRB Interrupt request Vector number . . . I Interrupt controller UE SYSCR Legend ISCR: IER: ISR: IPRA: IPRB: SYSCR: IRQ sense control register IRQ enable register IRQ status register Interrupt priority register A Interrupt priority register B System control register UI CCR Figure 5.1 Interrupt Controller Block Diagram Rev. 2.0, 03/01, page 80 of 822 5.1.3 Pin Configuration Table 5.1 lists the interrupt pins. Table 5.1 Name Nonmaskable interrupt External interrupt request 5 to 0 Interrupt Pins Abbreviation NMI ,545 to ,540 I/O Input Input Function Nonmaskable external interrupt, rising edge or falling edge selectable Maskable external interrupts, falling edge or level sensing selectable 5.1.4 Register Configuration Table 5.2 lists the registers of the interrupt controller. Table 5.2 Address* H'FFF2 H'FFF4 H'FFF5 H'FFF6 H'FFF8 H'FFF9 1 Interrupt Controller Registers Name System control register IRQ sense control register IRQ enable register IRQ status register Interrupt priority register A Interrupt priority register B Abbreviation SYSCR ISCR IER ISR IPRA IPRB R/W R/W R/W R/W R/(W)* R/W R/W 2 Initial Value H'0B H'00 H'00 H'00 H'00 H'00 Notes: 1. Lower 16 bits of the address. 2. Only 0 can be written, to clear flags. Rev. 2.0, 03/01, page 81 of 822 5.2 5.2.1 Register Descriptions System Control Register (SYSCR) SYSCR is an 8-bit readable/writable register that controls software standby mode, selects the action of the UI bit in CCR, selects the NMI edge, and enables or disables the on-chip RAM. Only bits 3 and 2 are described here. For the other bits, see section 3.3, System Control Register (SYSCR). SYSCR is initialized to H'0B by a reset and in hardware standby mode. It is not initialized in software standby mode. Bit Initial value Read/Write 7 SSBY 0 R/W 6 STS2 0 R/W 5 STS1 0 R/W 4 STS0 0 R/W 3 UE 1 R/W 2 NMIEG 0 R/W 1 -- 1 -- 0 RAME 1 R/W RAM enable Reserved bit Standby timer select 2 to 0 Software standby NMI edge select Selects the NMI input edge User bit enable Selects whether to use the UI bit in CCR as a user bit or interrupt mask bit Rev. 2.0, 03/01, page 82 of 822 Bit 3--User Bit Enable (UE): Selects whether to use the UI bit in CCR as a user bit or an interrupt mask bit. Bit 3: UE 0 1 Description UI bit in CCR is used as interrupt mask bit UI bit in CCR is used as user bit (Initial value) Bit 2--NMI Edge Select (NMIEG): Selects the NMI input edge. Bit 2: NMIEG 0 1 Description Interrupt is requested at falling edge of NMI input Interrupt is requested at rising edge of NMI input (Initial value) 5.2.2 Interrupt Priority Registers A and B (IPRA, IPRB) IPRA and IPRB are 8-bit readable/writable registers that control interrupt priority. Rev. 2.0, 03/01, page 83 of 822 Interrupt Priority Register A (IPRA): IPRA is an 8-bit readable/writable register in which interrupt priority levels can be set. Bit Initial value Read/Write 7 IPRA7 0 R/W 6 IPRA6 0 R/W 5 IPRA5 0 R/W 4 IPRA4 0 R/W 3 IPRA3 0 R/W 2 IPRA2 0 R/W 1 IPRA1 0 R/W 0 IPRA0 0 R/W Priority level A0 Selects the priority level of ITU channel 2 interrupt requests Priority level A1 Selects the priority level of ITU channel 1 interrupt requests Priority level A2 Selects the priority level of ITU channel 0 interrupt requests Priority level A3 Selects the priority level of WDT and refresh controller interrupt requests Priority level A4 Selects the priority level of IRQ4 and IRQ 5 interrupt requests Priority level A5 Selects the priority level of IRQ 2 and IRQ 3 interrupt requests Priority level A6 Selects the priority level of IRQ1 interrupt requests Priority level A7 Selects the priority level of IRQ 0 interrupt requests IPRA is initialized to H'00 by a reset and in hardware standby mode. Rev. 2.0, 03/01, page 84 of 822 Bit 7--Priority Level A7 (IPRA7): Selects the priority level of IRQ0 interrupt requests. Bit 7: IPRA7 0 1 Description IRQ0 interrupt requests have priority level 0 (Non-priority) IRQ0 interrupt requests have priority level 1 (Priority) (Initial value) Bit 6--Priority Level A6 (IPRA6): Selects the priority level of IRQ1 interrupt requests. Bit 6: IPRA6 0 1 Description IRQ1 interrupt requests have priority level 0 (Non-priority) IRQ1 interrupt requests have priority level 1 (Priority) (Initial value) Bit 5--Priority Level A5 (IPRA5): Selects the priority level of IRQ2 and IRQ3 interrupt requests. Bit 5: IPRA5 0 1 Description IRQ2 and IRQ3 interrupt requests have priority level 0 (Non-priority) (Initial value) IRQ2 and IRQ3 interrupt requests have priority level 1 (Priority) Bit 4--Priority Level A4 (IPRA4): Selects the priority level of IRQ4 and IRQ5 interrupt requests. Bit 4: IPRA4 0 1 Description IRQ4 and IRQ5 interrupt requests have priority level 0 (Non-priority) (Initial value) IRQ4 and IRQ5 interrupt requests have priority level 1 (Priority) Bit 3--Priority Level A3 (IPRA3): Selects the priority level of WDT and refresh controller interrupt requests. Bit 3: IPRA3 0 1 Description WDT and refresh controller interrupt requests have priority level 0 (Non-priority) (Initial value) WDT and refresh controller interrupt requests have priority level 1 (Priority) Rev. 2.0, 03/01, page 85 of 822 Bit 2--Priority Level A2 (IPRA2): Selects the priority level of ITU channel 0 interrupt requests. Bit 2: IPRA2 0 1 Description ITU channel 0 interrupt requests have priority level 0 (Non-priority) (Initial value) ITU channel 0 interrupt requests have priority level 1 (Priority) Bit 1--Priority Level A1 (IPRA1): Selects the priority level of ITU channel 1 interrupt requests. Bit 1: IPRA1 0 1 Description ITU channel 1 interrupt requests have priority level 0 (Non-priority) (Initial value) ITU channel 1 interrupt requests have priority level 1 (Priority) Bit 0--Priority Level A0 (IPRA0): Selects the priority level of ITU channel 2 interrupt requests. Bit 0: IPRA0 0 1 Description ITU channel 2 interrupt requests have priority level 0 (Non-priority) (Initial value) ITU channel 2 interrupt requests have priority level 1 (Priority) Rev. 2.0, 03/01, page 86 of 822 Interrupt Priority Register B (IPRB): IPRB is an 8-bit readable/writable register in which interrupt priority levels can be set. Bit Initial value Read/Write 7 IPRB7 0 R/W 6 IPRB6 0 R/W 5 IPRB5 0 R/W 4 -- 0 R/W 3 IPRB3 0 R/W 2 IPRB2 0 R/W 1 IPRB1 0 R/W 0 -- 0 R/W Reserved bit Priority level B1 Selects the priority level of A/D converter interrupt request Priority level B2 Selects the priority level of SCI channel 1 interrupt requests Priority level B3 Selects the priority level of SCI channel 0 interrupt requests Reserved bit Priority level B5 Selects the priority level of DMAC interrupt requests (channels 0 and 1) Priority level B6 Selects the priority level of ITU channel 4 interrupt requests Priority level B7 Selects the priority level of ITU channel 3 interrupt requests IPRB is initialized to H'00 by a reset and in hardware standby mode. Rev. 2.0, 03/01, page 87 of 822 Bit 7--Priority Level B7 (IPRB7): Selects the priority level of ITU channel 3 interrupt requests. Bit 7: IPRB7 0 1 Description ITU channel 3 interrupt requests have priority level 0 (low priority) (Initial value) ITU channel 3 interrupt requests have priority level 1 (high priority) Bit 6--Priority Level B6 (IPRB6): Selects the priority level of ITU channel 4 interrupt requests. Bit 6: IPRB6 0 1 Description ITU channel 4 interrupt requests have priority level 0 (low priority) (Initial value) ITU channel 4 interrupt requests have priority level 1 (high priority) Bit 5--Priority Level B5 (IPRB5): Selects the priority level of DMAC interrupt requests (channels 0 and 1). Bit 5: IPRB5 0 1 Description DMAC interrupt requests (channels 0 and 1) have priority level 0 (low priority) (Initial value) DMAC interrupt requests (channels 0 and 1) have priority level 1 (high priority) Bit 4--Reserved: This bit can be written and read, but it does not affect interrupt priority. Rev. 2.0, 03/01, page 88 of 822 Bit 3--Priority Level B3 (IPRB3): Selects the priority level of SCI channel 0 interrupt requests. Bit 3: IPRB3 0 1 Description SCI0 interrupt requests have priority level 0 (low priority) SCI0 interrupt requests have priority level 1 (high priority) (Initial value) Bit 2--Priority Level B2 (IPRB2): Selects the priority level of SCI channel 1 interrupt requests. Bit 2: IPRB2 0 1 Description SCI1 interrupt requests have priority level 0 (low priority) SCI1 interrupt requests have priority level 1 (high priority) (Initial value) Bit 1--Priority Level B1 (IPRB1): Selects the priority level of A/D converter interrupt requests. Bit 1: IPRB1 0 1 Description A/D converter interrupt requests have priority level 0 (low priority) (Initial value) A/D converter interrupt requests have priority level 1 (high priority) Bit 0--Reserved: This bit can be written and read, but it does not affect interrupt priority. Rev. 2.0, 03/01, page 89 of 822 5.2.3 IRQ Status Register (ISR) ISR is an 8-bit readable/writable register that indicates the status of IRQ0 to IRQ5 interrupt requests. Bit Initial value Read/Write 7 -- 0 -- 6 -- 0 -- 5 IRQ5F 0 R/(W)* 4 IRQ4F 0 R/(W)* 3 IRQ3F 0 R/(W)* 2 IRQ2F 0 R/(W)* 1 IRQ1F 0 R/(W)* 0 IRQ0F 0 R/(W)* Reserved bits IRQ 5 to IRQ0 flags These bits indicate IRQ 5 to IRQ 0 interrupt request status Note: * Only 0 can be written, to clear flags. ISR is initialized to H'00 by a reset and in hardware standby mode. Bits 7 and 6--Reserved: Read-only bits, always read as 0. Bits 5 to 0--IRQ5 to IRQ0 Flags (IRQ5F to IRQ0F): These bits indicate the status of IRQ5 to IRQ0 interrupt requests. Bits 5 to 0: IRQ5F to IRQ0F 0 Description [Clearing conditions] (Initial value) 0 is written in IRQnF after reading the IRQnF flag when IRQnF = 1. IRQnSC = 0, ,54Q input is high, and interrupt exception handling is carried out. IRQnSC = 1 and IRQn interrupt exception handling is carried out. 1 [Setting conditions] IRQnSC = 0 and ,54Q input is low. IRQnSC = 1 and a falling edge occurs in ,54Q input Note: n = 5 to 0 Rev. 2.0, 03/01, page 90 of 822 5.2.4 IRQ Enable Register (IER) IER is an 8-bit readable/writable register that enables or disables IRQ0 to IRQ5 interrupt requests. Bit Initial value Read/Write 7 -- 0 R/W 6 -- 0 R/W 5 IRQ5E 0 R/W 4 IRQ4E 0 R/W 3 IRQ3E 0 R/W 2 IRQ2E 0 R/W 1 IRQ1E 0 R/W 0 IRQ0E 0 R/W Reserved bits IRQ 5 to IRQ0 enable These bits enable or disable IRQ 5 to IRQ 0 interrupts IER is initialized to H'00 by a reset and in hardware standby mode. Bits 7 and 6--Reserved: These bits can be written and read, but they do not enable or disable interrupts. Bits 5 to 0--IRQ5 to IRQ0 Enable (IRQ5E to IRQ0E): These bits enable or disable IRQ5 to IRQ0 interrupts. Bits 5 to 0: IRQ5E to IRQ0E 0 1 Description IRQ5 to IRQ0 interrupts are disabled IRQ5 to IRQ0 interrupts are enabled (Initial value) Rev. 2.0, 03/01, page 91 of 822 5.2.5 IRQ Sense Control Register (ISCR) ISCR is an 8-bit readable/writable register that selects level sensing or falling-edge sensing of the inputs at pins ,545 to ,540. Bit Initial value Read/Write 7 -- 0 R/W 6 -- 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W IRQ5SC IRQ4SC IRQ3SC IRQ2SC IRQ1SC IRQ0SC Reserved bits IRQ 5 to IRQ0 sense control These bits select level sensing or falling-edge sensing for IRQ 5 to IRQ 0 interrupts ISCR is initialized to H'00 by a reset and in hardware standby mode. Bits 7 and 6--Reserved: These bits can be written and read, but they do not select level or falling-edge sensing. Bits 5 to 0--IRQ5 to IRQ0 Sense Control (IRQ5SC to IRQ0SC): These bits select whether interrupts IRQ5 to IRQ0 are requested by level sensing of pins ,545 to ,540, or by falling-edge sensing. Bits 5 to 0: IRQ5SC to IRQ0SC 0 1 Description Interrupts are requested when ,545 to ,540 inputs are low Interrupts are requested by falling-edge input at ,545 to ,540 (Initial value) Rev. 2.0, 03/01, page 92 of 822 5.3 Interrupt Sources The interrupt sources include external interrupts (NMI, IRQ0 to IRQ5) and 30 internal interrupts. 5.3.1 External Interrupts There are seven external interrupts: NMI, and IRQ0 to IRQ5. Of these, NMI, IRQ0, IRQ1, and IRQ2 can be used to exit software standby mode. NMI: NMI is the highest-priority interrupt and is always accepted, regardless of the states of the I and UI bits in CCR. The NMIEG bit in SYSCR selects whether an interrupt is requested by the rising or falling edge of the input at the NMI pin. NMI interrupt exception handling has vector number 7. IRQ0 to IRQ5 Interrupts: These interrupts are requested by input signals at pins ,540 to ,545. The IRQ0 to IRQ5 interrupts have the following features. * ISCR settings can select whether an interrupt is requested by the low level of the input at pins ,540 to ,545, or by the falling edge. * IER settings can enable or disable the IRQ0 to IRQ5 interrupts. Interrupt priority levels can be assigned by four bits in IPRA (IPRA7 to IPRA4). * The status of IRQ0 to IRQ5 interrupt requests is indicated in ISR. The ISR flags can be cleared to 0 by software. Figure 5.2 shows a block diagram of interrupts IRQ0 to IRQ5. IRQnSC IRQnF Edge/level sense circuit input S R Clear signal Note: n = 5 to 0 Q IRQn interrupt request IRQnE Figure 5.2 Block Diagram of Interrupts IRQ0 to IRQ5 Rev. 2.0, 03/01, page 93 of 822 Figure 5.3 shows the timing of the setting of the interrupt flags (IRQnF). input pin IRQnF Note: n = 5 to 0 Figure 5.3 Timing of Setting of IRQnF Interrupts IRQ0 to IRQ5 have vector numbers 12 to 17. These interrupts are detected regardless of whether the corresponding pin is set for input or output. When using a pin for external interrupt input, clear its DDR bit to 0 and do not use the pin for chip select output, refresh output, or SCI input or output. 5.3.2 Internal Interrupts Thirty internal interrupts are requested from the on-chip supporting modules. * Each on-chip supporting module has status flags for indicating interrupt status, and enable bits for enabling or disabling interrupts. * Interrupt priority levels can be assigned in IPRA and IPRB. * ITU and SCI interrupt requests can activate the DMAC, in which case no interrupt request is sent to the interrupt controller, and the I and UI bits are disregarded. 5.3.3 Interrupt Exception Vector Table Table 5.3 lists the interrupt sources, their vector addresses, and their default priority order. In the default priority order, smaller vector numbers have higher priority. The priority of interrupts other than NMI can be changed in IPRA and IPRB. The priority order after a reset is the default order shown in table 5.3. Rev. 2.0, 03/01, page 94 of 822 Table 5.3 Interrupt Sources, Vector Addresses, and Priority Origin External pins Vector Number 7 12 13 14 15 16 17 -- Watchdog timer Refresh controller -- ITU channel 0 18 19 20 21 22 23 24 Vector Address* H'001C to H'001F H'0030 to H'0033 H'0034 to H0037 H'0038 to H'003B H'003C to H'003F H'0040 to H'0043 H'0044 to H'0047 H'0048 to H'004B H'004C to H'004F H'0050 to H'0053 H'0054 to H'0057 H'0058 to H'005B H'005C to H'005F H'0060 to H'0063 IPRA2 IPRA3 IPRA4 IPR -- IPRA7 IPRA6 IPRA5 Priority High Interrupt Source NMI IRQ0 IRQ1 IRQ2 IRQ3 IRQ4 IRQ5 Reserved WOVI (interval timer) CMI (compare match) Reserved IMIA0 (compare match/ input capture A0) IMIB0 (compare match/ input capture B0) OVI0 (overflow 0) Reserved IMIA1 (compare match/ input capture A1) IMIB1 (compare match/ input capture B1) OVI1 (overflow 1) Reserved 25 H'0064 to H'0067 26 -- ITU channel 1 27 28 H'0068 to H'006B H'006C to H'006F H'0070 to H'0073 IPRA1 29 H'0074 to H'0077 30 -- 31 H'0078 to H'007B H'007C to H'007F Low Rev. 2.0, 03/01, page 95 of 822 Interrupt Source IMIA2 (compare match/ input capture A2) IMIB2 (compare match/ input capture B2) OVI2 (overflow 2) Reserved IMIA3 (compare match/ input capture A3) IMIB3 (compare match/ input capture B3) OVI3 (overflow 3) Reserved IMIA4 (compare match/ input capture A4) IMIB4 (compare match/ input capture B4) OVI4 (overflow 4) Reserved DEND0A DEND0B DEND1A DEND1B Reserved Origin ITU channel 2 Vector Number 32 Vector Address* H'0080 to H'0083 IPR IPRA0 Priority High 33 H'0084 to H'0087 34 -- ITU channel 3 35 36 H'0088 to H'008B H'008C to H'008F H'0090 to H'0093 IPRB7 37 H'0094 to H'0097 38 -- ITU channel 4 39 40 H'0098 to H'009B H'009C to H'009F H'00A0 to H'00A3 IPRB6 41 H'00A4 to H'00A7 42 -- DMAC 43 44 45 46 47 -- 48 49 50 51 H'00A8 to H'00AB H'00AC to H'00AF H'00B0 to H'00B3 H'00B4 to H'00B7 H'00B8 to H'00BB H'00BC to H'00BF H'00C0 to H'00C3 H'00C4 to H'00C7 H'00C8 to H'00CB H'00CC to H'00CF -- IPRB5 Low Rev. 2.0, 03/01, page 96 of 822 Interrupt Source ERI0 (receive error 0) RXI0 (receive data full 0) TXI0 (transmit data empty 0) TEI0 (transmit end 0) ERI1 (receive error 1) RXI1 (receive data full 1) TXI1 (transmit data empty 1) TEI1 (transmit end 1) ADI (A/D end) Origin SCI channel 0 Vector Number 52 53 54 55 Vector Address* H'00D0 to H'00D3 H'00D4 to H'00D7 H'00D8 to H'00DB H'00DC to H'00DF H'00E0 to H'00E3 H'00E4 to H'00E7 H'00E8 to H'00EB H'00EC to H'00EF H'00F0 to H'00F3 IPR IPRB3 Priority High SCI channel 1 56 57 58 59 IPRB2 A/D 60 IPRB1 Low Note: * Lower 16 bits of the address. Rev. 2.0, 03/01, page 97 of 822 5.4 5.4.1 Interrupt Operation Interrupt Handling Process The H8/3052F handles interrupts differently depending on the setting of the UE bit. When UE = 1, interrupts are controlled by the I bit. When UE = 0, interrupts are controlled by the I and UI bits. Table 5.4 indicates how interrupts are handled for all setting combinations of the UE, I, and UI bits. NMI interrupts are always accepted except in the reset and hardware standby states. IRQ interrupts and interrupts from the on-chip supporting modules have their own enable bits. Interrupt requests are ignored when the enable bits are cleared to 0. Table 5.4 SYSCR UE 1 I 0 1 0 0 1 UE, I, and UI Bit Settings and Interrupt Handling CCR UI -- -- -- 0 1 Description All interrupts are accepted. Interrupts with priority level 1 have higher priority. No interrupts are accepted except NMI. All interrupts are accepted. Interrupts with priority level 1 have higher priority. NMI and interrupts with priority level 1 are accepted. No interrupts are accepted except NMI. UE = 1: Interrupts IRQ0 to IRQ5 and interrupts from the on-chip supporting modules can all be masked by the I bit in the CPU's CCR. Interrupts are masked when the I bit is set to 1, and unmasked when the I bit is cleared to 0. Interrupts with priority level 1 have higher priority. Figure 5.4 is a flowchart showing how interrupts are accepted when UE = 1. Rev. 2.0, 03/01, page 98 of 822 Program execution state No Interrupt requested? Yes Yes NMI No No Priority level 1? Yes No No Pending IRQ 0 Yes IRQ 0 No Yes IRQ 1 Yes IRQ 1 Yes No ADI Yes ADI Yes No I=0 Yes Save PC and CCR I 1 Read vector address Branch to interrupt service routine Figure 5.4 Process Up to Interrupt Acceptance when UE = 1 Rev. 2.0, 03/01, page 99 of 822 1. If an interrupt condition occurs and the corresponding interrupt enable bit is set to 1, an interrupt request is sent to the interrupt controller. 2. When the interrupt controller receives one or more interrupt requests, it selects the highestpriority request, following the IPR interrupt priority settings, and holds other requests pending. If two or more interrupts with the same IPR setting are requested simultaneously, the interrupt controller follows the priority order shown in table 5.3. 3. The interrupt controller checks the I bit. If the I bit is cleared to 0, the selected interrupt request is accepted. If the I bit is set to 1, only NMI is accepted; other interrupt requests are held pending. 4. When an interrupt request is accepted, interrupt exception handling starts after execution of the current instruction has been completed. 5. In interrupt exception handling, PC and CCR are saved to the stack area. The PC value that is saved indicates the address of the first instruction that will be executed after the return from the interrupt service routine. 6. Next the I bit is set to 1 in CCR, masking all interrupts except NMI. 7. The vector address of the accepted interrupt is generated, and the interrupt service routine starts executing from the address indicated by the contents of the vector address. UE = 0: The I and UI bits in the CPU's CCR and the IPR bits enable three-level masking of IRQ0 to IRQ5 interrupts and interrupts from the on-chip supporting modules. * Interrupt requests with priority level 0 are enabled when the I bit is cleared to 0, and disabled when the I bit is set to 1. * Interrupt requests with priority level 1 are enabled when the I bit or UI bit is cleared to 0, and disabled when the I bit and UI bit are both set to 1. For example, if the interrupt enable bits of all interrupt requests are set to 1, and IPRA and IPRB are set to H'20 and H'00, respectively (giving IRQ2 and IRQ3 interrupt requests priority over other interrupts), interrupts are enabled and disabled as follows: a. If I = 0, all interrupts are enabled (priority order: NMI > IRQ2 > IRQ3 > IRQ0 ...). b. If I = 1 and UI = 0, only NMI, IRQ2, and IRQ3 are enabled. c. If I = 1 and UI = 1, all interrupts are disabled except NMI. Figure 5.5 shows the transitions among the above states. Rev. 2.0, 03/01, page 100 of 822 I0 a. All interrupts are enabled I 1, UI 0 b. Only NMI, IRQ 2 , and IRQ 3 are enabled I0 Exception handling, or I 1, UI 1 UI 0 Exception handling, or UI 1 c. All interrupts are disabled except NMI Figure 5.5 Interrupt Enable/Disable State Transitions (Example) Figure 5.6 is a flowchart showing how interrupts are accepted when UE = 0. 1. If an interrupt condition occurs and the corresponding interrupt enable bit is set to 1, an interrupt request is sent to the interrupt controller. 2. When the interrupt controller receives one or more interrupt requests, it selects the highestpriority request, following the IPR interrupt priority settings, and holds other requests pending. If two or more interrupts with the same IPR setting are requested simultaneously, the interrupt controller follows the priority order shown in table 5.3. 3. The interrupt controller checks the I bit. If the I bit is cleared to 0, the interrupt request is accepted regardless of its IPR setting. The value of the UI bit is immaterial. If the I bit is set to 1 and the UI bit is cleared to 0, only interrupt requests with priority level 1 are accepted; interrupt requests with priority level 0 are held pending. If the I bit and UI bit are both set to 1, the interrupt request is held pending. 4. When an interrupt request is accepted, interrupt exception handling starts after execution of the current instruction has been completed. 5. In interrupt exception handling, PC and CCR are saved to the stack area. The PC value that is saved indicates the address of the first instruction that will be executed after the return from the interrupt service routine. 6. The I and UI bits are set to 1 in CCR, masking all interrupts except NMI. 7. The vector address of the accepted interrupt is generated, and the interrupt service routine starts executing from the address indicated by the contents of the vector address. Rev. 2.0, 03/01, page 101 of 822 Program execution state No Interrupt requested? Yes Yes NMI No No Priority level 1? Yes No No Pending IRQ 0 Yes IRQ 0 No Yes IRQ 1 Yes IRQ 1 Yes No ADI Yes ADI Yes No I=0 Yes No UI = 0 Yes I=0 Yes No Save PC and CCR I 1, UI 1 Read vector address Branch to interrupt service routine Figure 5.6 Process Up to Interrupt Acceptance when UE = 0 Rev. 2.0, 03/01, page 102 of 822 5.4.2 Interrupt accepted Interrupt level decision and wait for end of instruction Instruction Internal prefetch processing Stack Vector fetch Prefetch of interrupt Internal service routine processing instruction Interrupt request signal (1) (3) (5) (7) (9) (11) (13) Interrupt Exception Handling Sequence Address bus , High (2) (4) (6) (8) D15 to D0 (10) (12) (14) (1) Instruction prefetch address (not executed; return address, same as PC contents) (2), (4) Instruction code (not executed) (3) Instruction prefetch address (not executed) (5) SP - 2 (7) SP - 4 (6), (8) PC and CCR saved to stack (9), (11) Vector address (10), (12) Starting address of interrupt service routine (contents of vector address) (13) Starting address of interrupt service routine; (13) = (10), (12) (14) First instruction of interrupt service routine Figure 5.7 shows the interrupt sequence in mode 2 when the program area and stack area are in 16-bit, two-state access space in external memory. Figure 5.7 Interrupt Sequence (Mode 2, Two-State Access, Stack in External Memory) Rev. 2.0, 03/01, page 103 of 822 Note: Mode 2, with program code and stack in external memory area accessed in two states via 16-bit bus. 5.4.3 Interrupt Response Time Table 5.5 indicates the interrupt response time from the occurrence of an interrupt request until the first instruction of the interrupt service routine is executed. Table 5.5 Interrupt Response Time External Memory On-Chip Memory 2* 1 8-Bit Bus 2 States 2* 1 16-Bit Bus 2 States 2* 4 1 No. 1 2 Item Interrupt priority decision Maximum number of states until end of current instruction Saving PC and CCR to stack Vector fetch Instruction prefetch* Internal processing* 2 3 3 States 2* 1 3 States 2* 1 1 to 23 1 to 27 1 to 31* 1 to 23 1 to 25* 4 3 4 5 6 Total 4 4 4 4 19 to 41 8 8 8 4 31 to 57 12* 12* 12* 4 4 4 4 4 4 19 to 41 6* 6* 6* 4 4 4 4 4 4 43 to 73 25 to 49 Notes: 1. 1 state for internal interrupts. 2. Prefetch after the interrupt is accepted and prefetch of the first instruction in the interrupt service routine. 3. Internal processing after the interrupt is accepted and internal processing after prefetch. 4. The number of states increases if wait states are inserted in external memory access. Rev. 2.0, 03/01, page 104 of 822 5.5 5.5.1 Usage Notes Contention between Interrupt Generation and Disabling When an instruction clears an interrupt enable bit to 0 to disable the interrupt, the interrupt is not actually disabled until after execution of the instruction is completed. Thus, if an interrupt occurs while a BCLR, MOV, or other instruction is being executed to clear its interrupt enable bit to 0, at the instant when execution of the instruction ends the interrupt is still enabled, so its interrupt exception handling is carried out. If a higher-priority interrupt is also requested, however, interrupt exception handling for the higher-priority interrupt is carried out, and the lower-priority interrupt is ignored. This also applies when an interrupt source flag is cleared to 0. Figure 5.8 shows an example in which an IMIEA bit is cleared to 0 in TIER of the ITU. TIER write cycle by CPU Internal address bus Internal write signal IMIEA IMIA exception handling TIER address IMIA IMFA interrupt signal Figure 5.8 Contention between Interrupt and Interrupt-Disabling Instruction This type of contention will not occur if the interrupt is masked when the interrupt enable bit or flag is cleared to 0. Rev. 2.0, 03/01, page 105 of 822 5.5.2 Instructions that Inhibit Interrupts The LDC, ANDC, ORC, and XORC instructions inhibit interrupts. When an interrupt occurs, after determining the interrupt priority, the interrupt controller requests a CPU interrupt. If the CPU is currently executing one of these interrupt-inhibiting instructions, however, when the instruction is completed the CPU always continues by executing the next instruction. 5.5.3 Interrupts during EEPMOV Instruction Execution The EEPMOV.B and EEPMOV.W instructions differ in their reaction to interrupt requests. When the EEPMOV.B instruction is executing a transfer, no interrupts are accepted until the transfer is completed, not even NMI. When the EEPMOV.W instruction is executing a transfer, interrupt requests other than NMI are not accepted until the transfer is completed. If NMI is requested, NMI exception handling starts at a transfer cycle boundary. The PC value saved on the stack is the address of the next instruction. Programs should be coded as follows to allow for NMI interrupts during EEPMOV.W execution: L1: EEPMOV.W MOV.W R4,R4 BNE L1 5.5.4 Notes on Use of External Interrupts The specifications provide for the IRQnF flag to be cleared by first reading the flag while it is set to 1, then writing 0 to it. However, there are cases in which the IRQnF flag is erroneously cleared, preventing execution of interrupt exception handling, simply by writing 0 to the flag, without first reading 1 from it. This occurs when the following conditions are fulfilled. Setting Conditions 1. When using multiple external interrupts (IRQa, IRQb) 2. When different clearing methods are used for the IRQaF flag and IRQbF flag, with the IRQaF flag cleared by writing 0 to it, and the IRQbF flag cleared by hardware. 3. IRQaF flag clears and bit operation command is being used for the IRQ status register (ISR) or the ISR is being read in bytes; IRQaF flag's bits clear and other bit values read in bits are written in bytes. Rev. 2.0, 03/01, page 106 of 822 Occurrence Conditions 1. If an ISR register read is executed to clear the IRQaF flag while IRQaF = 1, and then the IRQbF flag is cleared by the initiation of interrupt exception handling. 2. If there is contention between IRQaF flag clearing and IRQbF generation (IRQaF flag setting) (when IRQbF = 0 at the time of the ISR read to clear the IRQaF flag, but IRQbF is set to 1 before the write to ISR). If above setting conditions 1 to 3 and occurrence conditions 1 and 2 are all fulfilled, IRQbF will be cleared erroneously when the ISR write in occurrence condition 2 is executed, and so interrupt exception handling will not be carried out. However, the IRQbF flag will not be cleared erroneously if 0 is written to it at least once between occurrence conditions 1 and 2. IRQaF Read Write 1 0 Read Write 1 0 IRQbF Read Write IRQb 1 1 Execution Read Write 0 0 Clear in error Occurrence condition 1 Occurrence condition 2 Figure 5.9 IRQnF Flag when Interrupt Processing Is Not Conducted Either of the following methods can be used to prevent this problem. * Solution 1 When IRQaF flag clears, do not use the bit computation command, read the ISR in bytes. When IRQaF only is 0 write all other bits as 1 in bytes. For example, if a = 0 MOV.B @ISR,R0L MOV.B #HFE,R0L Rev. 2.0, 03/01, page 107 of 822 MOV.B R0L,@ISR * Solution 2 During IRQb interrupt processing, carry out IRQbF flag clear dummy processing. For example, if b = 1 IRQB MOV.B #HFD,R0L MOV.B R0L,@ISR * * * Rev. 2.0, 03/01, page 108 of 822 Section 6 Bus Controller 6.1 Overview The H8/3052F has an on-chip bus controller that divides the address space into eight areas and can assign different bus specifications to each. This enables different types of memory to be connected easily. A bus arbitration function of the bus controller controls the operation of the DMA controller (DMAC) and refresh controller. The bus controller can also release the bus to an external device. 6.1.1 Features Features of the bus controller are listed below. * Independent settings for address areas 0 to 7 128-kbyte areas in 1-Mbyte modes; 2-Mbyte areas in 16-Mbyte modes. Chip select signals (&60 to &67) can be output for areas 0 to 7. Areas can be designated for 8-bit or 16-bit access. Areas can be designated for two-state or three-state access. * Four wait modes Programmable wait mode, pin auto-wait mode, and pin wait modes 0 and 1 can be selected. Zero to three wait states can be inserted automatically. * Bus arbitration function A built-in bus arbiter grants the bus right to the CPU, DMAC, refresh controller, or an external bus master. Rev. 2.0, 03/01, page 109 of 822 6.1.2 Block Diagram Figure 6.1 shows a block diagram of the bus controller. 0 to 7 ABWCR Internal address bus ASTCR Area decoder Chip select control signals WCER CSCR Bus control circuit Internal signals Bus mode control signal Bus size control signal Access state control signal Wait request signal Internal data bus Wait-state controller WCR Internal signals CPU bus request signal DMAC bus request signal Refresh controller bus request signal CPU bus acknowledge signal DMAC bus acknowledge signal Refresh controller bus acknowledge signal BRCR Bus arbiter Legend ABWCR: ASTCR: WCER: WCR: BRCR: CSCR: Bus width control register Access state control register Wait state controller enable register Wait control register Bus release control register Chip select control register Figure 6.1 Block Diagram of Bus Controller Rev. 2.0, 03/01, page 110 of 822 6.1.3 Pin Configuration Table 6.1 summarizes the bus controller's input/output pins. Table 6.1 Name Chip select 0 to 7 Address strobe Read High write Bus Controller Pins Abbreviation &60 to &67 $6 5' +:5 I/O Output Output Output Output Function Strobe signals selecting areas 0 to 7 Strobe signal indicating valid address output on the address bus Strobe signal indicating reading from the external address space Strobe signal indicating writing to the external address space, with valid data on the upper data bus (D15 to D8) Strobe signal indicating writing to the external address space, with valid data on the lower data bus (D7 to D0) Wait request signal for access to external three-state-access areas Request signal for releasing the bus to an external device Acknowledge signal indicating the bus is released to an external device Low write /:5 Output Wait Bus request Bus acknowledge :$,7 %5(4 %$&. Input Input Output Rev. 2.0, 03/01, page 111 of 822 6.1.4 Register Configuration Table 6.2 summarizes the bus controller's registers. Table 6.2 Bus Controller Registers Initial Value Address* H'FFEC H'FFED H'FFEE H'FFEF H'FFF3 H'FF5F Name Bus width control register Access state control register Wait control register Wait state controller enable register Bus release control register Chip select control register Abbreviation ABWCR ASTCR WCR WCER BRCR CSCR R/W R/W R/W R/W R/W R/W R/W Modes 1, 3, 5, 6 H'FF H'FF H'F3 H'FF H'FE H'0F Modes 2, 4, 7 H'00 H'FF H'F3 H'FF H'FE H'0F Note: * Lower 16 bits of the address. 6.2 6.2.1 Register Descriptions Bus Width Control Register (ABWCR) ABWCR is an 8-bit readable/writable register that selects 8-bit or 16-bit access for each area. Bit Initial Modes 1, 3, 5, 6, 7 value Modes 2, 4 Read/Write 7 ABW7 1 0 R/W 6 ABW6 1 0 R/W 5 ABW5 1 0 R/W 4 ABW4 1 0 R/W 3 ABW3 1 0 R/W 2 ABW2 1 0 R/W 1 ABW1 1 0 R/W 0 ABW0 1 0 R/W Bits selecting bus width for each area When ABWCR contains H'FF (selecting 8-bit access for all areas), the chip operates in 8-bit bus mode: the upper data bus (D15 to D8) is valid, and port 4 is an input/output port. When at least one bit is cleared to 0 in ABWCR, the chip operates in 16-bit bus mode with a 16-bit data bus (D15 to D0). In modes 1, 3, 5, 6, and 7 ABWCR is initialized to H'FF by a reset and in hardware standby mode. In modes 2 and 4 ABWCR is initialized to H'00 by a reset and in hardware standby mode. ABWCR is not initialized in software standby mode. Rev. 2.0, 03/01, page 112 of 822 Bits 7 to 0--Area 7 to 0 Bus Width Control (ABW7 to ABW0): These bits select 8-bit access or 16-bit access to the corresponding address areas. Bits 7 to 0: ABW7 to ABW0 0 1 Description Areas 7 to 0 are 16-bit access areas Areas 7 to 0 are 8-bit access areas ABWCR specifies the bus width of external memory areas. The bus width of on-chip memory and registers is fixed and does not depend on ABWCR settings. These settings are therefore meaningless in single-chip mode (mode 7). 6.2.2 Access State Control Register (ASTCR) ASTCR is an 8-bit readable/writable register that selects whether each area is accessed in two states or three states. Bit Initial value Read/Write 7 AST7 1 R/W 6 AST6 1 R/W 5 AST5 1 R/W 4 AST4 1 R/W 3 AST3 1 R/W 2 AST2 1 R/W 1 AST1 1 R/W 0 AST0 1 R/W Bits selecting number of states for access to each area ASTCR is initialized to H'FF by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 0--Area 7 to 0 Access State Control (AST7 to AST0): These bits select whether the corresponding area is accessed in two or three states. Bits 7 to 0: AST7 to AST0 0 1 Description Areas 7 to 0 are accessed in two states Areas 7 to 0 are accessed in three states (Initial value) ASTCR specifies the number of states in which external areas are accessed. On-chip memory and registers are accessed in a fixed number of states that does not depend on ASTCR settings. These settings are therefore meaningless in single-chip mode (mode 7). Rev. 2.0, 03/01, page 113 of 822 6.2.3 Wait Control Register (WCR) WCR is an 8-bit readable/writable register that selects the wait mode for the wait-state controller (WSC) and specifies the number of wait states. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 WMS1 0 R/W 2 WMS0 0 R/W 1 WC1 1 R/W 0 WC0 1 R/W Reserved bits Wait count 1/0 These bits select the number of wait states inserted Wait mode select 1/0 These bits select the wait mode WCR is initialized to H'F3 by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 4--Reserved: Read-only bits, always read as 1. Bits 3 and 2--Wait Mode Select 1 and 0 (WMS1/0): These bits select the wait mode. Bit 3: WMS1 0 1 Bit 2: WMS0 0 1 0 1 Description Programmable wait mode Pin wait mode 1 Pin auto-wait mode (Initial value) No wait states inserted by wait-state controller Bits 1 and 0--Wait Count 1 and 0 (WC1/0): These bits select the number of wait states inserted in access to external three-state-access areas. Bit 1: WC1 0 1 Bit 0: WC0 0 1 0 1 Description No wait states inserted by wait-state controller 1 state inserted 2 states inserted 3 states inserted (Initial value) Rev. 2.0, 03/01, page 114 of 822 6.2.4 Wait State Controller Enable Register (WCER) WCER is an 8-bit readable/writable register that enables or disables wait-state control of external three-state-access areas by the wait-state controller. Bit Initial value Read/Write 7 WCE7 1 R/W 6 WCE6 1 R/W 5 WCE5 1 R/W 4 WCE4 1 R/W 3 WCE3 1 R/W 2 WCE2 1 R/W 1 WCE1 1 R/W 0 WCE0 1 R/W Wait-state controller enable 7 to 0 These bits enable or disable wait-state control WCER is initialized to H'FF by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 0--Wait-State Controller Enable 7 to 0 (WCE7 to WCE0): These bits enable or disable wait-state control of external three-state-access areas. Bits 7 to 0: WCE7 to WCE0 0 1 Description Wait-state control disabled (pin wait mode 0) Wait-state control enabled (Initial value) Since WCER enables or disables wait-state control of external three-state-access areas, these settings are meaningless in single-chip mode (mode 7). Rev. 2.0, 03/01, page 115 of 822 6.2.5 Bus Release Control Register (BRCR) BRCR is an 8-bit readable/writable register that enables address output on bus lines A23 to A21 and enables or disables release of the bus to an external device. Bit Initial value Read/ Modes 1, 2, 5, 7 Write Modes 3, 4, 6 7 A23E 1 -- R/W 6 A22E 1 -- R/W 5 A21E 1 -- R/W 4 -- 1 -- -- 3 -- 1 -- -- 2 -- 1 -- -- 1 -- 1 -- -- 0 BRLE 0 R/W R/W Address 23 to 21 enable These bits enable PA 6 to PA 4 to be used for A 23 to A 21 address output Reserved bits Bus release enable Enables or disables release of the bus to an external device BRCR is initialized to H'FE by a reset and in hardware standby mode. It is not initialized in software standby mode. Bit 7--Address 23 Enable (A23E): Enables PA4 to be used as the A23 address output pin. Writing 0 in this bit enables A23 address output from PA4. In modes other than 3, 4, and 6 this bit cannot be modified and PA4 has its ordinary input/output functions. Bit 7: A23E 0 1 Description PA4 is the A23 address output pin PA4 is the PA4/TP4/TIOCA1 input/output pin (Initial value) Bit 6--Address 22 Enable (A22E): Enables PA5 to be used as the A22 address output pin. Writing 0 in this bit enables A22 address output from PA5. In modes other than 3, 4, and 6 this bit cannot be modified and PA5 has its ordinary input/output functions. Bit 6: A22E 0 1 Description PA5 is the A22 address output pin PA5 is the PA5/TP5/TIOCB1 input/output pin (Initial value) Rev. 2.0, 03/01, page 116 of 822 Bit 5--Address 21 Enable (A21E): Enables PA6 to be used as the A21 address output pin. Writing 0 in this bit enables A21 address output from PA6. In modes other than 3, 4, and 6 this bit cannot be modified and PA6 has its ordinary input/output functions. Bit 5: A21E 0 1 Description PA6 is the A21 address output pin PA6 is the PA6/TP6/TIOCA2 input/output pin (Initial value) Bits 4 to 1--Reserved: Read-only bits, always read as 1. Bit 0--Bus Release Enable (BRLE): Enables or disables release of the bus to an external device. Bit 0: BRLE 0 1 Description The bus cannot be released to an external device; %5(4 and %$&. can be used as input/output pins (Initial value) The bus can be released to an external device Rev. 2.0, 03/01, page 117 of 822 6.2.6 Chip Select Control Register (CSCR) CSCR is an 8-bit readable/writable register that enables or disables output of chip select signals (&67 to &64). If a chip select signal (&67 to &64) output is selected in this register, the corresponding pin functions as a chip select signal (&67 to &64) output, this function taking priority over other functions. CSCR cannot be modified in single-chip mode. Bit Initial value Read/Write 7 CS7E 0 R/W 6 CS6E 0 R/W 5 CS5E 0 R/W 4 CS4E 0 R/W 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Chip select 7 to 4 enable These bits enable or disable chip select signal output Reserved bits CSCR is initialized to H'0F by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 4--Chip Select 7 to 4 Enable (CS7E to CS4E): These bits enable or disable output of the corresponding chip select signal. Bit n: CSnE 0 1 Note: n = 7 to 4 Description Output of chip select signal CSn is disabled Output of chip select signal CSn is enabled (Initial value) Bits 3 to 0--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 118 of 822 6.3 6.3.1 Operation Area Division The external address space is divided into areas 0 to 7. Each area has a size of 128 kbytes in the 1-Mbyte modes, or 2 Mbytes in the 16-Mbyte modes. Figure 6.2 shows a general view of the memory map. H'00000 Area 0 (128 kbytes) H'1FFFF H'20000 Area 1 (128 kbytes) H'3FFFF H'40000 Area 2 (128 kbytes) H'5FFFF H'60000 Area 3 (128 kbytes) H'7FFFF H'80000 Area 4 (128 kbytes) H'9FFFF H'A0000 Area 5 (128 kbytes) H'BFFFF H'C0000 Area 6 (128 kbytes) H'DFFFF H'E0000 Area 7 (128 kbytes) On-chip RAM * 1, *2 External address space*3 H'FFFFF On-chip registers *1 a. 1-Mbyte modes with on-chip ROM disabled (modes 1 and 2) H'000000 Area 0 (2 Mbytes) H'1FFFFF H'200000 Area 1 (2 Mbytes) H'3FFFFF H'400000 Area 2 (2 Mbytes) H'5FFFFF H'600000 Area 3 (2 Mbytes) H'7FFFFF H'800000 Area 4 (2 Mbytes) H'9FFFFF H'A00000 Area 5 (2 Mbytes) H'BFFFFF H'C00000 Area 6 (2 Mbytes) H'DFFFFF H'E00000 Area 7 (2 Mbytes) On-chip RAM * 1, *2 External address space*3 H'FFFFFF On-chip registers *1 b. 16-Mbyte modes with on-chip ROM disabled (modes 3 and 4) H'00000 H'1FFFF H'20000 H'3FFFF H'40000 H'5FFFF H'60000 H'7FFFF H'80000 Area 4 (128 kbytes) H'9FFFF H'A0000 Area 5 (128 kbytes) H'BFFFF H'C0000 Area 6 (128 kbytes) H'DFFFF H'E0000 Area 7 (128 kbytes) On-chip RAM * 1, *2 External address space*3 H'FFFFF On-chip registers*1 c. 1-Mbyte mode with on-chip ROM enabled (mode 5) On-chip ROM *1 H'000000 H'1FFFFF H'200000 H'3FFFFF H'400000 On-chip ROM *1 Area 0 (2 Mbytes) Area 1 (2 Mbytes) Area 2 (2 Mbytes) H'5FFFFF H'600000 Area 3 (2 Mbytes) H'7FFFFF H'800000 Area 4 (2 Mbytes) H'9FFFFF H'A00000 Area 5 (2 Mbytes) H'BFFFFF H'C00000 Area 6 (2 Mbytes) H'DFFFFF H'E00000 Area 7 (2 Mbytes) On-chip RAM * 1, *2 External address space*3 H'FFFFFF On-chip registers*1 d. 16-Mbyte mode with on-chip ROM enabled (mode 6) Notes: 1. The on-chip ROM, on-chip RAM, and on-chip registers have a fixed bus width and are accessed in a fixed number of states. 2. When the RAME bit is cleared to 0 in SYSCR, this area conforms to the specifications of area 7. 3. This external address area conforms to the specifications of area 7. Figure 6.2 Access Area Map for Modes 1 to 6 Rev. 2.0, 03/01, page 119 of 822 Chip select signals (&67 to &60) can be output for areas 7 to 0. The bus specifications for each area can be selected in ABWCR, ASTCR, WCER, and WCR as shown in table 6.3. Table 6.3 ABWCR ABWn 0 Bus Specifications ASTCR ASTn 0 1 WCER WCEn -- 0 1 WCR WMS1 -- -- 0 1 WMS0 -- -- 0 1 0 1 -- -- 0 1 1 0 1 Bus Width 16 16 16 16 16 16 8 8 8 8 8 8 Bus Specifications Access States Wait Mode 2 3 3 3 3 3 2 3 3 3 3 3 Disabled Pin wait mode 0 Programmable wait mode Disabled Pin wait mode 1 Pin auto-wait mode Disabled Pin wait mode 0 Programmable wait mode Disabled Pin wait mode 1 Pin auto-wait mode 1 0 1 -- 0 1 -- -- 0 Note: n = 7 to 0 Rev. 2.0, 03/01, page 120 of 822 6.3.2 Chip Select Signals For each of areas 7 to 0, the H8/3052F can output a chip select signal (&67 to &60) that goes low to indicate when the area is selected. Figure 6.3 shows the output timing of a &6n signal (n = 7 to 0). Output of &63 to &60: Output of &63 to &60 is enabled or disabled in the data direction register (DDR) of the corresponding port. In the expanded modes with on-chip ROM disabled, a reset leaves pin &60 in the output state and pins &63 to &61 in the input state. To output chip select signals &63, to &61 the corresponding DDR bits must be set to 1. In the expanded modes with on-chip ROM enabled, a reset leaves pins &63 to &60 in the input state. To output chip select signals &63, to &60 the corresponding DDR bits must be set to 1. For details see section 9, I/O Ports. Output of &67 to &64: Output of &67 to &64 is enabled or disabled in the chip select control register (CSCR). A reset leaves pins &67 to &64 in the input state. To output chip select signals &67 to &64, the corresponding CSCR bits must be set to 1. For details see section 9, I/O Ports. Address bus External address in area n n Figure 6.3 &6n Output Timing (n = 7 to 0) When the on-chip ROM, on-chip RAM, and on-chip registers are accessed, &67 and &60 remain high. The &6n signals are decoded from the address signals. They can be used as chip select signals for SRAM and other devices. Rev. 2.0, 03/01, page 121 of 822 6.3.3 Data Bus The H8/3052F allows either 8-bit access or 16-bit access to be designated for each of areas 0 to 7. An 8-bit-access area uses the upper data bus (D15 to D8). A 16-bit-access area uses both the upper data bus (D15 to D8) and lower data bus (D7 to D0). In read access the 5' signal applies without distinction to both the upper and lower data bus. In write access the +:5 signal applies to the upper data bus, and the /:5 signal applies to the lower data bus. Table 6.4 indicates how the two parts of the data bus are used under different access conditions. Table 6.4 Area 8-bit-access area 16-bit-access area Access Conditions and Data Bus Usage Valid Access Read/W Size rite Address Strobe -- Byte Read Write Read Write Word Read Write -- -- Even Odd Even Odd -- -- +:5 /:5 5' +:5, /:5 5' +:5 5' Valid Invalid Valid Undetermined data Valid Valid Upper Data Bus (D15 to D8) Valid Lower Data Bus (D7 to D0) Invalid Undetermined data Invalid Valid Undetermined data Valid Valid Valid Note: Undetermined data means that unpredictable data is output. Invalid means that the bus is in the input state and the input is ignored. Rev. 2.0, 03/01, page 122 of 822 6.3.4 Bus Control Signal Timing 8-Bit, Three-State-Access Areas: Figure 6.4 shows the timing of bus control signals for an 8-bit, three-state-access area. The upper address bus (D15 to D8) is used to access these areas. The /:5 pin is always high. Wait states can be inserted. Bus cycle T1 T2 T3 Address bus External address in area n n Read access D15 to D8 Valid D 7 to D 0 Invalid High Write access D15 to D8 Valid D 7 to D 0 Undetermined data Note: n = 7 to 0 Figure 6.4 Bus Control Signal Timing for 8-Bit, Three-State-Access Area Rev. 2.0, 03/01, page 123 of 822 8-Bit, Two-State-Access Areas: Figure 6.5 shows the timing of bus control signals for an 8-bit, two-state-access area. The upper address bus (D15 to D8) is used to access these areas. The /:5 pin is always high. Wait states cannot be inserted. Bus cycle T1 o T2 Address bus External address in area n n Read access D15 to D8 Valid D 7 to D 0 Invalid High Write access D15 to D8 Valid D 7 to D 0 Undetermined data Note: n = 7 to 0 Figure 6.5 Bus Control Signal Timing for 8-Bit, Two-State-Access Area Rev. 2.0, 03/01, page 124 of 822 16-Bit, Three-State-Access Areas: Figures 6.6 to 6.8 show the timing of bus control signals for a 16-bit, three-state-access area. In these areas, the upper address bus (D15 to D8) is used to access even addresses and the lower address bus (D7 to D0) is used to access odd addresses. Wait states can be inserted. Bus cycle T1 T2 T3 Address bus Even external address in area n n Read access D15 to D8 Valid D 7 to D 0 Invalid High Write access D15 to D8 Valid D 7 to D 0 Note: n = 7 to 0 Undetermined data Figure 6.6 Bus Control Signal Timing for 16-Bit, Three-State-Access Area (1) (Byte Access to Even Address) Rev. 2.0, 03/01, page 125 of 822 Bus cycle T1 T2 T3 Address bus Odd external address in area n n Read access D15 to D8 Invalid D 7 to D 0 Valid High Write access D15 to D8 Undetermined data D 7 to D 0 Valid Note: n = 7 to 0 Figure 6.7 Bus Control Signal Timing for 16-Bit, Three-State-Access Area (2) (Byte Access to Odd Address) Rev. 2.0, 03/01, page 126 of 822 Bus cycle T1 T2 T3 Address bus External address in area n n Read access D15 to D8 Valid D 7 to D 0 Valid Write access D15 to D8 Valid D 7 to D 0 Valid Note: n = 7 to 0 Figure 6.8 Bus Control Signal Timing for 16-Bit, Three-State-Access Area (3) (Word Access) Rev. 2.0, 03/01, page 127 of 822 16-Bit, Two-State-Access Areas: Figures 6.9 to 6.11 show the timing of bus control signals for a 16-bit, two-state-access area. In these areas, the upper address bus (D15 to D8) is used to access even addresses and the lower address bus (D7 to D0) is used to access odd addresses. Wait states cannot be inserted. Bus cycle T1 T2 Address bus Even external address in area n n Read access D15 to D8 Valid D 7 to D 0 Invalid High Write access D15 to D8 Valid D 7 to D 0 Undetermined data Note: n = 7 to 0 Figure 6.9 Bus Control Signal Timing for 16-Bit, Two-State-Access Area (1) (Byte Access to Even Address) Rev. 2.0, 03/01, page 128 of 822 Bus cycle T1 o T2 Address bus Odd external address in area n n Read access D15 to D8 Invalid D 7 to D 0 High Valid Write access D15 to D8 Undetermined data D 7 to D 0 Valid Note: n = 7 to 0 Figure 6.10 Bus Control Signal Timing for 16-Bit, Two-State-Access Area (2) (Byte Access to Odd Address) Rev. 2.0, 03/01, page 129 of 822 Bus cycle T1 o T2 Address bus External address in area n n Read access D15 to D8 Valid D 7 to D 0 Valid Write access D15 to D8 Valid D 7 to D 0 Valid Note: n = 7 to 0 Figure 6.11 Bus Control Signal Timing for 16-Bit, Two-State-Access Area (3) (Word Access) Rev. 2.0, 03/01, page 130 of 822 6.3.5 Wait Modes Four wait modes can be selected as shown in table 6.5. Table 6.5 ASTCR ASTn Bit 0 1 Wait Mode Selection WCER WCEn Bit -- 0 1 WCR WMS1 Bit WMS0 Bit WSC Control -- -- 0 1 -- -- 0 1 0 1 Disabled Disabled Enabled Enabled Enabled Enabled Wait Mode No wait states Pin wait mode 0 Programmable wait mode No wait states Pin wait mode 1 Pin auto-wait mode Note: n = 7 to 0 Rev. 2.0, 03/01, page 131 of 822 Wait Mode in Areas Where Wait-State Controller is Disabled: External three-state access areas in which the wait-state controller is disabled (ASTn = 1, WCEn = 0) operate in pin wait mode 0. The other wait modes are unavailable. The settings of bits WMS1 and WMS0 are ignored in these areas. * Pin Wait Mode 0 Wait states can only be inserted by :$,7 pin control. During access to an external three-stateaccess area, if the :$,7 pin is low at the fall of the system clock () in the T2 state, a wait state (TW) is inserted. If the :$,7 pin remains low, wait states continue to be inserted until the :$,7 signal goes high. Figure 6.12 shows the timing. Inserted by WAIT signal T1 T2 TW TW T3 * * * WAIT pin Address bus External address AS RD Read access Data bus Read data HWR , LWR Write access Data bus Write data Note: * Arrows indicate time of sampling of the WAIT pin. Figure 6.12 Pin Wait Mode 0 Rev. 2.0, 03/01, page 132 of 822 Wait Modes in Areas Where Wait-State Controller is Enabled: External three-state access areas in which the wait-state controller is enabled (ASTn = 1, WCEn = 1) can operate in pin wait mode 1, pin auto-wait mode, or programmable wait mode, as selected by bits WMS1 and WMS0. Bits WMS1 and WMS0 apply to all areas, so all areas in which the wait-state controller is enabled operate in the same wait mode. * Pin Wait Mode 1 In all accesses to external three-state-access areas, the number of wait states (TW) selected by bits WC1 and WC0 are inserted. If the :$,7 pin is low at the fall of the system clock () in the last of these wait states, an additional wait state is inserted. If the :$,7 pin remains low, wait states continue to be inserted until the :$,7 signal goes high. Pin wait mode 1 is useful for inserting four or more wait states, or for inserting different numbers of wait states for different external devices. If the wait count is 0, this mode operates in the same way as pin wait mode 0. Figure 6.13 shows the timing when the wait count is 1 (WC1 = 0, WC0 = 1) and one additional wait state is inserted by :$,7 input. Inserted by wait count T1 T2 TW Inserted by WAIT signal TW T3 * pin External address * WAIT Address bus AS Read access RD Read data Data bus HWR, LWR Write access Data bus Write data Note: * Arrows indicate time of sampling of the WAIT pin. Figure 6.13 Pin Wait Mode 1 Rev. 2.0, 03/01, page 133 of 822 * Pin Auto-Wait Mode If the :$,7 pin is low, the number of wait states (TW) selected by bits WC1 and WC0 are inserted. In pin auto-wait mode, if the :$,7 pin is low at the fall of the system clock () in the T2 state, the number of wait states (TW) selected by bits WC1 and WC0 are inserted. No additional wait states are inserted even if the :$,7 pin remains low. Pin auto-wait mode can be used for an easy interface to low-speed memory, simply by routing the chip select signal to the :$,7 pin. Figure 6.14 shows the timing when the wait count is 1. T1 T2 T3 T1 T2 TW T3 * * WAIT Address bus External address External address AS RD Read access Data bus Read data Read data HWR , LWR Write access Data bus Write data Write data Note: * Arrows indicate time of sampling of the WAIT pin. Figure 6.14 Pin Auto-Wait Mode Rev. 2.0, 03/01, page 134 of 822 * Programmable Wait Mode The number of wait states (TW) selected by bits WC1 and WC0 are inserted in all accesses to external three-state-access areas. Figure 6.15 shows the timing when the wait count is 1 (WC1 = 0, WC0 = 1). T1 T2 TW T3 Address bus External address AS RD Read access Data bus Read data HWR, LWR Write access Data bus Write data Figure 6.15 Programmable Wait Mode Rev. 2.0, 03/01, page 135 of 822 Example of Wait State Control Settings: A reset initializes ASTCR and WCER to H'FF and WCR to H'F3, selecting programmable wait mode and three wait states for all areas. Software can select other wait modes for individual areas by modifying the ASTCR, WCER, and WCR settings. Figure 6.16 shows an example of wait mode settings. Area 0 Area 1 Area 2 Area 3 Area 4 Area 5 Area 6 Area 7 3-state-access area, programmable wait mode (3 states inserted) 3-state-access area, programmable wait mode (3 states inserted) 3-state-access area, pin wait mode 0 3-state-access area, pin wait mode 0 2-state-access area, no wait states inserted 2-state-access area, no wait states inserted 2-state-access area, no wait states inserted 2-state-access area, no wait states inserted Bit: ASTCR H'0F: 7 0 6 0 5 0 4 0 3 1 2 1 1 1 0 1 WCER H'33: 0 0 1 1 0 0 1 1 WCR H'F3: -- -- -- -- 0 0 1 1 Note: Wait states cannot be inserted in areas designated for two-state access by ASTCR. Figure 6.16 Wait Mode Settings (Example) Rev. 2.0, 03/01, page 136 of 822 6.3.6 Interconnections with Memory (Example) For each area, the bus controller can select two- or three-state access and an 8- or 16-bit data bus width. In three-state-access areas, wait states can be inserted in a variety of modes, simplifying the connection of both high-speed and low-speed devices. Figure 6.18 shows an example of interconnections between the H8/3052F and memory. Figure 6.17 shows a memory map for this example. A 256-kword x 16-bit EPROM is connected to area 0. This device is accessed in three states via a 16-bit bus. Two 32-kword x 8-bit SRAM devices (SRAM1 and SRAM2) are connected to area 1. These devices are accessed in two states via a 16-bit bus. One 32-kword x 8-bit SRAM (SRAM3) is connected to area 2. This device is accessed via an 8-bit bus, using three-state access with an additional wait state inserted in pin auto-wait mode. H'000000 EPROM H'07FFFF Not used H'1FFFFF H'200000 SRAM 1, 2 H'20FFFF H'210000 Not used H'3FFFFF H'400000 SRAM 3 H'407FFF Area 2 8-bit, three-state-access area (one auto-wait state) Not used H'5FFFFF Area 1 16-bit, two-state-access area Area 0 16-bit, three-state-access area On-chip RAM H'FFFFFF On-chip registers Figure 6.17 Memory Map (Example) Rev. 2.0, 03/01, page 137 of 822 EPROM A18 to A 1 A 17 to A 0 I/O 15 to I/O8 H8/3052F CS 0 CS 1 CS 2 SRAM1 (even addresses) A15 to A 1 A14 to A 0 I/O 7 to I/O 0 WAIT RD HWR LWR SRAM2 (odd addresses) A15 to A 1 A 14 to A 0 I/O 7 to I/O 0 CS OE WE D15 to D 8 D 7 to D 0 SRAM3 A14 to A 0 A 14 to A 0 I/O 7 to I/O 0 CS OE WE CS OE WE I/O 7 to I/O 0 CE OE A 23 to A 0 Figure 6.18 Interconnections with Memory (Example) Rev. 2.0, 03/01, page 138 of 822 6.3.7 Bus Arbiter Operation The bus controller has a built-in bus arbiter that arbitrates between different bus masters. There are four bus masters: the CPU, DMA controller (DMAC), refresh controller, and an external bus master. When a bus master has the bus right it can carry out read, write, or refresh access. Each bus master uses a bus request signal to request the bus right. At fixed times the bus arbiter determines priority and uses a bus acknowledge signal to grant the bus to a bus master, which can then operate using the bus. The bus arbiter checks whether the bus request signal from a bus master is active or inactive, and returns an acknowledge signal to the bus master if the bus request signal is active. When two or more bus masters request the bus, the highest-priority bus master receives an acknowledge signal. The bus master that receives an acknowledge signal can continue to use the bus until the acknowledge signal is deactivated. The bus master priority order is: (High) External bus master > refresh controller > DMAC > CPU (Low) The bus arbiter samples the bus request signals and determines priority at all times, but it does not always grant the bus immediately, even when it receives a bus request from a bus master with higher priority than the current bus master. Each bus master has certain times at which it can release the bus to a higher-priority bus master. CPU: The CPU is the lowest-priority bus master. If the DMAC, refresh controller, or an external bus master requests the bus while the CPU has the bus right, the bus arbiter transfers the bus right to the bus master that requested it. The bus right is transferred at the following times: * The bus right is transferred at the boundary of a bus cycle. If word data is accessed by two consecutive byte accesses, however, the bus right is not transferred between the two byte accesses. * If another bus master requests the bus while the CPU is performing internal operations, such as executing a multiply or divide instruction, the bus right is transferred immediately. The CPU continues its internal operations. * If another bus master requests the bus while the CPU is in sleep mode, the bus right is transferred immediately. Rev. 2.0, 03/01, page 139 of 822 DMAC: When the DMAC receives an activation request, it requests the bus right from the bus arbiter. If the DMAC is bus master and the refresh controller or an external bus master requests the bus, the bus arbiter transfers the bus right from the DMAC to the bus master that requested the bus. The bus right is transferred at the following times. The bus right is transferred when the DMAC finishes transferring 1 byte or 1 word. A DMAC transfer cycle consists of a read cycle and a write cycle. The bus right is not transferred between the read cycle and the write cycle. There is a priority order among the DMAC channels. For details see section 8.4.9, MultipleChannel Operation. Refresh Controller: When a refresh cycle is requested, the refresh controller requests the bus right from the bus arbiter. When the refresh cycle is completed, the refresh controller releases the bus. For details see section 7, Refresh Controller. External Bus Master: When the BRLE bit is set to 1 in BRCR, the bus can be released to an external bus master. The external bus master has highest priority, and requests the bus right from the bus arbiter by driving the %5(4 signal low. Once the external bus master gets the bus, it keeps the bus right until the %5(4 signal goes high. While the bus is released to an external bus master, the H8/3052F holds the address bus and data bus control signals ($6, 5', +:5, and /:5) in the high-impedance state, holds the chip select signals high (&6n: n = 7 to 0), and holds the %$&. pin in the low output state. The bus arbiter samples the %5(4 pin at the rise of the system clock (). If %5(4 is low, the bus is released to the external bus master at the appropriate opportunity. The %5(4 signal should be held low until the %$&. signal goes low. When the %5(4 pin is high in two consecutive samples, the %$&. signal is driven high to end the bus-release cycle. Rev. 2.0, 03/01, page 140 of 822 Figure 6.19 shows the timing when the bus right is requested by an external bus master during a read cycle in a two-state-access area. There is a minimum interval of two states from when the %5(4 signal goes low until the bus is released. CPU cycles T1 Address bus T2 External bus released CPU cycles High-impedance Address High level n High-impedance Data bus High-impedance , High , High-impedance Minimum 2 cycles 1 n = 7 to 0 1 Low 2 3 4, 5 High 6 signal is sampled at rise of T1 state. signal goes low at end of CPU read cycle, releasing bus right to external bus master. pin continues to be sampled while bus is released to external bus master. signal is sampled twice consecutively. signal goes high, ending bus-release cycle. 2 3 4 5 6 Figure 6.19 External-Bus-Released State (Two-State-Access Area during Read Cycle) Rev. 2.0, 03/01, page 141 of 822 6.4 6.4.1 Usage Notes Connection to Dynamic RAM and Pseudo-Static RAM A different bus control signal timing applies when dynamic RAM or pseudo-static RAM is connected to area 3. For details see section 7, Refresh Controller. 6.4.2 Register Write Timing ABWCR, ASTCR, and WCER Write Timing: Data written to ABWCR, ASTCR, or WCER takes effect starting from the next bus cycle. Figure 6.20 shows the timing when an instruction fetched from area 0 changes area 0 from three-state access to two-state access. T1 Address bus T2 T3 T1 T2 T3 T1 T2 ASTCR address 3-state access to area 0 2-state access to area 0 Figure 6.20 ASTCR Write Timing Rev. 2.0, 03/01, page 142 of 822 DDR Write Timing: Data written to a data direction register (DDR) to change a &6n pin from &6n output to generic input, or vice versa, takes effect starting from the T3 state of the DDR write cycle. Figure 6.21 shows the timing when the &61 pin is changed from generic input to &61 output. T1 Address bus 1 T2 T3 P8DDR address High impedance Figure 6.21 DDR Write Timing BRCR Write Timing: Data written to switch between A23, A22, or A21 output and generic input or output takes effect starting from the T3 state of the BRCR write cycle. Figure 6.22 shows the timing when a pin is changed from generic input to A23, A22, or A21 output. T1 Address bus A 23 to A 21 T2 T3 BRCR address High impedance Figure 6.22 BRCR Write Timing Rev. 2.0, 03/01, page 143 of 822 6.4.3 %5(4 Input Timing After driving the %5(4 pin low, hold it low until %$&. goes low. If %5(4 returns to the high level before %$&. goes low, the bus arbiter may operate incorrectly. To terminate the external-bus-released state, hold the %5(4 signal high for at least three states. If %5(4 is high for too short an interval, the bus arbiter may operate incorrectly. 6.4.4 Transition To Software Standby Mode If contention occurs between a transition to software standby mode and a bus request from an external bus master, the bus may be released for one state just before the transition to software standby mode (see figure 6.23). When using software standby mode, clear the BRLE bit to 0 in BRCR before executing the SLEEP instruction. Bus-released state Software standby mode Address bus Strobe Figure 6.23 Contention between Bus-Released State and Software Standby Mode Rev. 2.0, 03/01, page 144 of 822 Section 7 Refresh Controller 7.1 Overview The H8/3052F has an on-chip refresh controller that enables direct connection of 16-bit-wide DRAM or pseudo-static RAM (PSRAM). DRAM or pseudo-static RAM can be directly connected to area 3 of the external address space. A maximum 128 kbytes can be connected in modes 1 and 2 (1-Mbyte modes). A maximum 2 Mbytes can be connected in modes 3, 4, and 6 (16-Mbyte modes). Systems that do not need to refresh DRAM or pseudo-static RAM can use the refresh controller as an 8-bit interval timer. When the refresh controller is not used, it can be independently halted to conserve power. For details see section 20.6, Module Standby Function. Note: The refresh function cannot be used in modes 5 and 7. 7.1.1 Features The refresh controller can be used for one of three functions: DRAM refresh control, pseudo-static RAM refresh control, or 8-bit interval timing. Features of the refresh controller are listed below. Features as a DRAM Refresh Controller * Enables direct connection of 16-bit-wide DRAM * Selection of 2&$6 or 2:( mode * Selection of 8-bit or 9-bit column address multiplexing for DRAM address input Examples: 1-Mbit DRAM: 8-bit row address x 8-bit column address 4-Mbit DRAM: 9-bit row address x 9-bit column address 4-Mbit DRAM: 10-bit row address x 8-bit column address * &$6-before-5$6 refresh control * Software-selectable refresh interval * Software-selectable self-refresh mode * Wait states can be inserted Rev. 2.0, 03/01, page 145 of 822 Features as a Pseudo-Static RAM Refresh Controller * 5)6+ signal output for refresh control * Software-selectable refresh interval * Software-selectable self-refresh mode * Wait states can be inserted Features as an Interval Timer * Refresh timer counter (RTCNT) can be used as an 8-bit up-counter * Selection of seven counter clock sources: /2, /8, /32, /128, /512, /2048, /4096 * Interrupts can be generated by compare match between RTCNT and the refresh time constant register (RTCOR) Rev. 2.0, 03/01, page 146 of 822 7.1.2 Block Diagram Figure 7.1 shows a block diagram of the refresh controller. /2, /8, /32, /128, /512, /2048, /4096 Refresh signal Clock selector Control logic Comparator CMI interrupt RTMCSR RFSHCR RTCOR RTCNT Module data bus Legend RTCNT: RTCOR: RTMCSR: RFSHCR: Refresh timer counter Refresh time constant register Refresh timer control/status register Refresh control register Figure 7.1 Block Diagram of Refresh Controller Rev. 2.0, 03/01, page 147 of 822 Internal data bus Bus interface 7.1.3 Pin Configuration Table 7.1 summarizes the refresh controller's input/output pins. Table 7.1 Refresh Controller Pins Signal Pin 5)6+ +:5 /:5 5' &63 Name Refresh Upper write/upper column address strobe Lower write/lower column address strobe Column address strobe/ write enable Row address strobe Abbr. 5)6+ 8:/8&$6 /://&$6 &$6/:( 5$6 I/O Output Output Output Output Output Function Goes low during refresh cycles; used to refresh DRAM and PSRAM Connects to the 8: pin of 2:( DRAM or 8&$6 pin of 2&$6 DRAM Connects to the /: pin of 2:( DRAM or /&$6 pin of 2&$6 DRAM Connects to the &$6 pin of 2:( DRAM or :( pin of 2&$6 DRAM Connects to the 5$6 pin of DRAM 7.1.4 Register Configuration Table 7.2 summarizes the refresh controller's registers. Table 7.2 Address* H'FFAC H'FFAD H'FFAE H'FFAF Refresh Controller Registers Name Refresh control register Refresh timer control/status register Refresh timer counter Refresh time constant register Abbreviation RFSHCR RTMCSR RTCNT RTCOR R/W R/W R/W R/W R/W Initial Value H'02 H'07 H'00 H'FF Note: * Lower 16 bits of the address. Rev. 2.0, 03/01, page 148 of 822 7.2 7.2.1 Register Descriptions Refresh Control Register (RFSHCR) RFSHCR is an 8-bit readable/writable register that selects the operating mode of the refresh controller. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 RFSHE 0 R/W 1 -- 1 -- 0 RCYCE 0 R/W SRFMD PSRAME DRAME CAS/WE M9/M8 Refresh cycle enable Enables or disables insertion of refresh cycles Reserved bit Refresh pin enable Enables refresh signal output from the refresh pin Address multiplex mode select Selects the number of column address bits Strobe mode select Selects 2 or 2 strobing of DRAM PSRAM enable and DRAM enable These bits enable or disable connection of pseudo-static RAM and DRAM Self-refresh mode Selects self-refresh mode RFSHCR is initialized to H'02 by a reset and in hardware standby mode. Rev. 2.0, 03/01, page 149 of 822 Bit 7--Self-Refresh Mode (SRFMD): Specifies DRAM or pseudo-static RAM self-refresh during software standby mode. When PSRAME = 1 and DRAME = 0, after the SRFMD bit is set to 1, pseudo-static RAM can be self-refreshed when the H8/3052F enters software standby mode. When PSRAME = 0 and DRAME = 1, after the SRFMD bit is set to 1, DRAM can be selfrefreshed when the H8/3052F enters software standby mode. In either case, the normal access state resumes on exit from software standby mode. Bit 7: SRFMD 0 1 Description DRAM or PSRAM self-refresh is disabled in software standby mode (Initial value) DRAM or PSRAM self-refresh is enabled in software standby mode Bit 6--PSRAM Enable (PSRAME) and Bit 5--DRAM Enable (DRAME): These bits enable or disable connection of pseudo-static RAM and DRAM to area 3 of the external address space. When DRAM or pseudo-static RAM is connected, the bus cycle and refresh cycle of area 3 consist of three states, regardless of the setting in the access state control register (ASTCR). If AST3 = 0 in ASTCR, wait states cannot be inserted. When the PSRAME or DRAME bit is set to 1, bits 0, 2, 3, and 4 in RFSHCR and registers RTMCSR, RTCNT, and RTCOR are write-disabled, except that the CMF flag in RTMCSR can be cleared by writing 0. Bit 6: PSRAME 0 Bit 5: DRAME 0 1 1 0 1 Description Can be used as an interval timer DRAM can be directly connected PSRAM can be directly connected Illegal setting (Initial value) (DRAM and PSRAM cannot be directly connected) Bit 4--Strobe Mode Select (CAS/:( Selects 2&$6 or 2:( mode. The setting of this bit is :(): :( valid when PSRAME = 0 and DRAME = 1. This bit is write-disabled when the PSRAME or DRAME bit is set to 1. Bit 4: CAS/:( :( 0 1 Description 2:( mode 2&$6 mode (Initial value) Rev. 2.0, 03/01, page 150 of 822 Bit 3--Address Multiplex Mode Select (M9/0; Selects 8-bit or 9-bit column addressing. 0;): 0; The setting of this bit is valid when PSRAME = 0 and DRAME = 1. This bit is write-disabled when the PSRAME or DRAME bit is set to 1. Bit 3: M9/0; 0; 0 1 Description 8-bit column address mode 9-bit column address mode (Initial value) Bit 2--Refresh Pin Enable (RFSHE): Enables or disables refresh signal output from the 5)6+ pin. This bit is write-disabled when the PSRAME or DRAME bit is set to 1. Bit 2: RFSHE 0 1 Description Refresh signal output at the 5)6+ pin is disabled (the 5)6+ pin can be used as a generic input/output port) (Initial value) Refresh signal output at the 5)6+ pin is enabled Bit 1--Reserved: Read-only bit, always read as 1. Bit 0--Refresh Cycle Enable (RCYCE): Enables or disables insertion of refresh cycles. The setting of this bit is valid when PSRAME = 1 or DRAME = 1. When PSRAME = 0 and DRAME = 0, refresh cycles are not inserted regardless of the setting of this bit. Bit 0: RCYCE 0 1 Description Refresh cycles are disabled Refresh cycles are enabled for area 3 (Initial value) Rev. 2.0, 03/01, page 151 of 822 7.2.2 Refresh Timer Control/Status Register (RTMCSR) RTMCSR is an 8-bit readable/writable register that selects the clock source for RTCNT. It also enables or disables interrupt requests when the refresh controller is used as an interval timer. Bit Initial value Read/Write 7 CMF 0 R/(W)* 6 CMIE 0 R/W 5 CKS2 0 R/W 4 CKS1 0 R/W 3 CKS0 0 R/W 2 -- 1 -- 1 -- 1 -- Reserved bits 0 -- 1 -- Clock select 2 to 0 These bits select an internal clock source for input to RTCNT Compare match interrupt enable Enables or disables the CMI interrupt requested by CMF Compare match flag Status flag indicating that RTCNT has matched RTCOR Note: * Only 0 can be written, to clear the flag. Bits 7 and 6 are initialized by a reset and in standby mode. Bits 5 to 3 are initialized by a reset and in hardware standby mode, but retain their previous values on transition to software standby mode. Bit 7--Compare Match Flag (CMF): This status flag indicates that the RTCNT and RTCOR values have matched. Bit 7: CMF 0 1 Description [Clearing condition] Cleared by reading CMF when CMF = 1, then writing 0 in CMF [Setting condition] When RTCNT = RTCOR Bit 6--Compare Match Interrupt Enable (CMIE): Enables or disables the CMI interrupt requested when the CMF flag is set to 1 in RTMCSR. The CMIE bit is always cleared to 0 when PSRAME = 1 or DRAME = 1. Bit 6: CMIE 0 1 Description The CMI interrupt requested by CMF is disabled The CMI interrupt requested by CMF is enabled (Initial value) Rev. 2.0, 03/01, page 152 of 822 Bits 5 to 3--Clock Select 2 to 0 (CKS2 to CKS0): These bits select an internal clock source for input to RTCNT. When used for refresh control, the refresh controller outputs a refresh request at periodic intervals determined by compare match between RTCNT and RTCOR. When used as an interval timer, the refresh controller generates CMI interrupts at periodic intervals determined by compare match. These bits are write-disabled when the PSRAME bit or DRAME bit is set to 1. Bit 5: CKS2 0 Bit 4: CKS1 0 1 1 0 1 Bit 3: CKS0 0 1 0 1 0 1 0 1 Description Clock input is disabled /2 clock source /8 clock source /32 clock source /128 clock source /512 clock source /2048 clock source /4096 clock source (Initial value) Bits 2 to 0--Reserved: Read-only bits, always read as 1. 7.2.3 Refresh Timer Counter (RTCNT) RTCNT is an 8-bit readable/writable up-counter. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W RTCNT is an up-counter that is incremented by an internal clock selected by bits CKS2 to CKS0 in RTMCSR. When RTCNT matches RTCOR (compare match), the CMF flag is set to 1 and RTCNT is cleared to H'00. RTCNT is write-disabled when the PSRAME bit or DRAME bit is set to 1. RTCNT is initialized to H'00 by a reset and in standby mode. Rev. 2.0, 03/01, page 153 of 822 7.2.4 Refresh Time Constant Register (RTCOR) RTCOR is an 8-bit readable/writable register that determines the interval at which RTCNT is compare matched. Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W 2 1 R/W 1 1 R/W 0 1 R/W RTCOR and RTCNT are constantly compared. When their values match, the CMF flag is set to 1 in RTMCSR, and RTCNT is simultaneously cleared to H'00. RTCOR is write-disabled when the PSRAME bit or DRAME bit is set to 1. RTCOR is initialized to H'FF by a reset and in hardware standby mode. In software standby mode it retains its previous value. Rev. 2.0, 03/01, page 154 of 822 7.3 7.3.1 Operation Overview One of three functions can be selected for the H8/3052F refresh controller: interfacing to DRAM connected to area 3, interfacing to pseudo-static RAM connected to area 3, or interval timing. Table 7.3 summarizes the register settings when these three functions are used. Table 7.3 Refresh Controller Settings Usage Register Settings RFSHCR SRFMD PSRAME DRAME CAS/:( M9/0; RFSHE RCYCE RTCOR RTMCSR CKS2 to CKS0 CMF CMIE P8DDR ABWCR P81DDR ABW3 DRAM Interface Selects self-refresh mode Cleared to 0 Set to 1 Selects 2&$6 or 2:( mode Selects column addressing mode Selects 5)6+ signal output Selects insertion of refresh cycles Refresh interval setting Set to 1 when RTCNT = RTCOR Cleared to 0 Set to 1 (&63 output) Cleared to 0 PSRAM Interface Selects self-refresh mode Set to 1 Cleared to 0 -- -- Selects 5)6+ signal output Selects insertion of refresh cycles Refresh interval setting Set to 1 when RTCNT = RTCOR Cleared to 0 Set to 1 (&63 output) -- Interval Timer Cleared to 0 Cleared to 0 Cleared to 0 -- -- Cleared to 0 -- Interrupt interval setting Set to 1 when RTCNT = RTCOR Enables or disables interrupt requests Set to 0 or 1 -- Rev. 2.0, 03/01, page 155 of 822 DRAM Interface: To set up area 3 for connection to 16-bit-wide DRAM, initialize RTCOR, RTMCSR, and RFSHCR in that order, clearing bit PSRAME to 0 and setting bit DRAME to 1. Set bit P81DDR to 1 in the port 8 data direction register (P8DDR) to enable &63 output. In ABWCR, make area 3 a 16-bit-access area. Pseudo-Static RAM Interface: To set up area 3 for connection to pseudo-static RAM, initialize RTCOR, RTMCSR, and RFSHCR in that order, setting bit PSRAME to 1 and clearing bit DRAME to 0. Set bit P81DDR to 1 in P8DDR to enable &63 output. Interval Timer: When PSRAME = 0 and DRAME = 0, the refresh controller operates as an interval timer. After setting RTCOR, select an input clock in RTMCSR and set the CMIE bit to 1. CMI interrupts will be requested at compare match intervals determined by RTCOR and bits CKS2 to CKS0 in RTMCSR. When setting RTCOR, RTMCSR, and RFSHCR, make sure that PSRAME = 0 and DRAME = 0. Writing is disabled when either of these bits is set to 1. Rev. 2.0, 03/01, page 156 of 822 7.3.2 DRAM Refresh Control Refresh Request Interval and Refresh Cycle Execution: The refresh request interval is determined by the settings of RTCOR and bits CKS2 to CKS0 in RTMCSR. Figure 7.2 illustrates the refresh request interval. RTCOR RTCNT H'00 Refresh request Figure 7.2 Refresh Request Interval (RCYCE = 1) Refresh requests are generated at regular intervals as shown in figure 7.2, but the refresh cycle is not actually executed until the refresh controller gets the bus right. Table 7.4 summarizes the relationship among area 3 settings, DRAM read/write cycles, and refresh cycles. Table 7.4 Area 3 Settings, DRAM Access Cycles, and Refresh Cycles Read/Write Cycle by CPU or DMAC * * * * 3 states Wait states cannot be inserted 3 states Wait states can be inserted Refresh Cycle * * * * 3 states Wait states cannot be inserted 3 states Wait states can be inserted Area 3 Settings 2-state-access area (AST3 = 0) 3-state-access area (AST3 = 1) To insert refresh cycles, set the RCYCE bit to 1 in RFSHCR. Figure 7.3 shows the state transitions for execution of refresh cycles. When the first refresh request occurs after exit from the reset state or standby mode, the refresh controller does not execute a refresh cycle, but goes into the refresh request pending state. Note this point when using a DRAM that requires a refresh cycle for initialization. Rev. 2.0, 03/01, page 157 of 822 When a refresh request occurs in the refresh request pending state, the refresh controller acquires the bus right, then executes a refresh cycle. If another refresh request occurs during execution of the refresh cycle, it is ignored. Exit from reset or standby mode Refresh request Refresh request pending state End of refresh cycle* Refresh request Refresh request * Requesting bus right Bus granted Refresh request * Executing refresh cycle Note: * A refresh request is ignored if it occurs while the refresh controller is requesting the bus right or executing a refresh cycle. Figure 7.3 State Transitions for Refresh Cycle Execution Rev. 2.0, 03/01, page 158 of 822 Address Multiplexing: Address multiplexing depends on the setting of the M9/0; bit in RFSHCR, as described in table 7.5. Figure 7.4 shows the address output timing. Address output is multiplexed only in area 3. Table 7.5 Address Multiplexing A23 to A10 A23 to A10 A23 to A10 A23 to A10 A9 A9 A9 A18 A8 A8 A9 A17 A7 A7 A16 A16 A6 A6 A15 A15 A5 A5 A14 A14 A4 A4 A13 A13 A3 A3 A12 A12 A2 A2 A11 A11 A1 A1 A10 A10 A0 A0 A0 A0 Address Pins Address signals during row address output Address signals during column address output M9/0; = 0 M9/0; = 1 T1 T2 T3 A 23 to A 9 , A 0 Address bus A 8 to A 1 A 8 to A1 Row address a. M9/ =0 A 23 to A 9, A 0 A 16 to A 9 Column address T1 T2 T3 A 23 to A10 , A 0 Address bus A 9 to A 1 A 9 to A1 Row address b. M9/ =1 A 23 to A10 , A 0 A 18 to A 10 Column address Figure 7.4 Multiplexed Address Output (Example without Wait States) Rev. 2.0, 03/01, page 159 of 822 2&$6 and 2:( Modes: The CAS/:( bit in RFSHCR can select two control modes for 16-bit&$6 :( wide DRAM: one using 8&$6 and /&$6; the other using 8: and /:. These DRAM pins correspond to H8/3052F pins as shown in table 7.6. Table 7.6 DRAM Pins and H8/3052F Pins DRAM Pin H8/3052F Pin +:5 /:5 5' &63 CAS/:( = 0 (2:( Mode) :( :( 8: /: &$6 5$6 CAS/:( = 1 (2&$6 Mode) :( &$6 8&$6 /&$6 :( 5$6 Figure 7.5 (1) shows the interface timing for 2:( DRAM. Figure 7.5 (2) shows the interface timing for 2&$6 DRAM. Read cycle Write cycle* Refresh cycle Address bus 3 Row Column Row Column Area 3 top address ( ) ( ) ( ) ( ) Note: * 16-bit access Figure 7.5 DRAM Control Signal Output Timing (1) (2:( Mode) :( Rev. 2.0, 03/01, page 160 of 822 Read cycle Write cycle* Refresh cycle Address bus 3 Row Column Row Column Area 3 top address ( ( ) ) ( ) ( ) Note: * 16-bit access Figure 7.5 DRAM Control Signal Output Timing (2) (2&$6 Mode) &$6 Refresh Cycle Priority Order: When there are simultaneous bus requests, the priority order is: (High) External bus master > refresh controller > DMA controller > CPU (Low) For details see section 6.3.7, Bus Arbiter Operation. Wait State Insertion: When bit AST3 is set to 1 in ASTCR, bus controller settings can cause wait states to be inserted into bus cycles and refresh cycles. For details see section 6.3.5, Wait Modes. Rev. 2.0, 03/01, page 161 of 822 Self-Refresh Mode: Some DRAM devices have a self-refresh function. After the SRFMD bit is set to 1 in RFSHCR, when a transition to software standby mode occurs, the &$6 and 5$6 outputs go low in that order so that the DRAM self-refresh function can be used. On exit from software standby mode, the &$6 and 5$6 outputs both go high. Table 7.7 shows the pin states in software standby mode. Figure 7.6 shows the signal output timing. Table 7.7 Pin States in Software Standby Mode (PSRAME = 0, DRAME = 1) Software Standby Mode SRFMD = 0 Signal +:5 /:5 5' &63 5)6+ CAS/:( = 0 :( High-impedance High-impedance High-impedance High High CAS/:( = 1 :( High-impedance High-impedance High-impedance High High SRFMD = 1 (self-refresh mode) CAS/:( = 0 :( High High Low Low Low CAS/:( = 1 :( Low Low High Low Low Rev. 2.0, 03/01, page 162 of 822 Software standby mode Address bus ( ) High-impedance Oscillator settling time 3 ( ) ( ) High ( ) High a. 2 mode (SRFMD = 1) Oscillator settling time Software standby mode Address bus ( ) High-impedance 3 ( ) ( ( ) ) b. 2 mode (SRFMD = 1) Figure 7.6 Signal Output Timing in Self-Refresh Mode (PSRAME = 0, DRAME = 1) Rev. 2.0, 03/01, page 163 of 822 Operation in Power-Down State: The refresh controller operates in sleep mode. It does not operate in hardware standby mode. In software standby mode RTCNT is initialized, but RFSHCR, RTMCSR bits 5 to 3, and RTCOR retain their settings prior to the transition to software standby mode. Example 1: Connection to 2WE 1-Mbit DRAM (1-Mbyte Mode): Figure 7.7 shows typical interconnections to a 2:( 1-Mbit DRAM, and the corresponding address map. Figure 7.8 shows a setup procedure to be followed by a program for this example. After power-up the DRAM must be refreshed to initialize its internal state. Initialization takes a certain length of time, which can be measured by using an interrupt from another timer module, or by counting the number of times RTMCSR bit 7 (CMF) is set. Note that no refresh cycle is executed for the first refresh request after exit from the reset state or standby mode (the first time the CMF flag is set; see figure 7.3). When using this example, check the DRAM device characteristics carefully and use a procedure that fits them. 2 WE 1-Mbit DRAM with x 16-bit organization H8/3052F A8 A7 A6 A5 A4 A3 A2 A1 CS 3 RD HWR LWR D15 to D 0 a. Interconnections (example) A7 A6 A5 A4 A3 A2 A1 A0 RAS CAS UW LW OE I/O 15 to I/O 0 H'60000 DRAM area H'7FFFF b. Address map Area 3 (1-Mbyte mode) Figure 7.7 Interconnections and Address Map for 2WE 1-Mbit DRAM (Example) Rev. 2.0, 03/01, page 164 of 822 Set area 3 for 16-bit access Set P81 DDR to 1 for 3 output Set RTCOR Set bits CKS2 to CKS0 in RTMCSR Write H'23 in RFSHCR Wait for DRAM to be initialized DRAM can be accessed Figure 7.8 Setup Procedure for 2WE 1-Mbit DRAM (1-Mbyte Mode) Rev. 2.0, 03/01, page 165 of 822 Example 2: Connection to 2WE 4-Mbit DRAM (16-Mbyte Mode): Figure 7.9 shows typical interconnections to a single 2:( 4-Mbit DRAM, and the corresponding address map. Figure 7.10 shows a setup procedure to be followed by a program for this example. The DRAM in this example has 10-bit row addresses and 8-bit column addresses. Its address area is H'600000 to H'67FFFF. 2 WE 4-Mbit DRAM with 10-bit row address, 8-bit column address, and x 16-bit organization H8/3052F A18 A17 A8 A7 A6 A5 A4 A3 A2 A1 CS 3 RD HWR LWR D15 to D 0 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 RAS CAS UW LW OE I/O 15 to I/O 0 a. Interconnections (example) H'600000 DRAM area H'67FFFF H'680000 Area 3 (16-Mbyte mode) Not used H'7FFFFF b. Address map Figure 7.9 Interconnections and Address Map for 2WE 4-Mbit DRAM (Example) Rev. 2.0, 03/01, page 166 of 822 Set area 3 for 16-bit access Set P81 DDR to 1 for 3 output Set RTCOR Set bits CKS2 to CKS0 in RTMCSR Write H'23 in RFSHCR Wait for DRAM to be initialized DRAM can be accessed Figure 7.10 Setup Procedure for 2WE 4-Mbit DRAM with 10-Bit Row Address and 8-Bit Column Address (16-Mbyte Mode) Rev. 2.0, 03/01, page 167 of 822 Example 3: Connection to 2&$6 4-Mbit DRAM (16-Mbyte Mode): Figure 7.11 shows typical &$6 interconnections to a single 2&$6 4-Mbit DRAM, and the corresponding address map. Figure 7.12 shows a setup procedure to be followed by a program for this example. The DRAM in this example has 9-bit row addresses and 9-bit column addresses. Its address area is H'600000 to H'67FFFF. 2 CAS 4-Mbit DRAM with 9-bit row address, 9-bit column address, and x 16-bit organization H8/3052F A9 A8 A7 A6 A5 A4 A3 A2 A1 CS 3 HWR LWR RD D15 to D 0 A8 A7 A6 A5 A4 A3 A2 A1 A0 RAS UCAS LCAS WE OE I/O 15 to I/O 0 a. Interconnections (example) H'600000 DRAM area H'67FFFF H'680000 Not used Area 3 (16-Mbyte mode) H'7FFFFF b. Address map Figure 7.11 Interconnections and Address Map for 2&$6 4-Mbit DRAM (Example) &$6 Rev. 2.0, 03/01, page 168 of 822 Set area 3 for 16-bit access Set P81 DDR to 1 for 3 output Set RTCOR Set bits CKS2 to CKS0 in RTMCSR Write H'3B in RFSHCR Wait for DRAM to be initialized DRAM can be accessed Figure 7.12 Setup Procedure for 2&$6 4-Mbit DRAM with 9-Bit Row Address and 9-Bit &$6 Column Address (16-Mbyte Mode) Rev. 2.0, 03/01, page 169 of 822 Example 4: Connection to Multiple 4-Mbit DRAM Chips (16-Mbyte Mode): Figure 7.13 shows an example of interconnections to two 2&$6 4-Mbit DRAM chips, and the corresponding address map. Up to four DRAM chips can be connected to area 3 by decoding upper address bits A19 and A20. Figure 7.14 shows a setup procedure to be followed by a program for this example. The DRAM in this example has 9-bit row addresses and 9-bit column addresses. Both chips must be refreshed simultaneously, so the 5)6+ pin must be used. 4-Mbit DRAM with 9-bit 2 row address, 9-bit column address, and x 16-bit organization H8/3052F A19 A 9 to A 1 No. 1 A 8 to A 0 I/O15 to I/O 0 A 8 to A 0 3 No. 2 D15 to D 0 a. Interconnections (example) H'600000 H'67FFFF H'680000 H'6FFFFF H'700000 No. 1 DRAM area No. 2 DRAM area I/O15 to I/O 0 Area 3 (16-Mbyte mode) Not used H'7FFFFF b. Address map Figure 7.13 Interconnections and Address Map for Multiple 2&$6 4-Mbit DRAM Chips &$6 (Example) Rev. 2.0, 03/01, page 170 of 822 Set area 3 for 16-bit access Set P81 DDR to 1 for 3 output Set RTCOR Set bits CKS2 to CKS0 in RTMCSR Write H'3F in RFSHCR Wait for DRAM to be initialized DRAM can be accessed Figure 7.14 Setup Procedure for Multiple 2&$6 4-Mbit DRAM Chips with 9-Bit Row &$6 Address and 9-Bit Column Address (16-Mbyte Mode) Rev. 2.0, 03/01, page 171 of 822 7.3.3 Pseudo-Static RAM Refresh Control Refresh Request Interval and Refresh Cycle Execution: The refresh request interval is determined as in a DRAM interface, by the settings of RTCOR and bits CKS2 to CKS0 in RTMCSR. The numbers of states required for pseudo-static RAM read/write cycles and refresh cycles are the same as for DRAM (see table 7.4). The state transitions are as shown in figure 7.3. Pseudo-Static RAM Control Signals: Figure 7.15 shows the control signals for pseudo-static RAM read, write, and refresh cycles. Read cycle Address bus 3 Write cycle * Refresh cycle Area 3 top address Note: * 16-bit access Figure 7.15 Pseudo-Static RAM Control Signal Output Timing Rev. 2.0, 03/01, page 172 of 822 Refresh Cycle Priority Order: When there are simultaneous bus requests, the priority order is: (High) External bus master > refresh controller > DMA controller > CPU (Low) For details see section 6.3.7, Bus Arbiter Operation. Wait State Insertion: When bit AST3 is set to 1 in ASTCR, the wait state controller (WSC) can insert wait states into bus cycles and refresh cycles. For details see section 6.3.5, Wait Modes. Self-Refresh Mode: Some pseudo-static RAM devices have a self-refresh function. After the SRFMD bit is set to 1 in RFSHCR, when a transition to software standby mode occurs, the H8/3052F' &63 output goes high and its 5)6+ output goes low so that the pseudo-static RAM self-refresh function can be used. On exit from software standby mode, the 5)6+ output goes high. Table 7.8 shows the pin states in software standby mode. Figure 7.16 shows the signal output timing. Table 7.8 Pin States in Software Standby Mode (PSRAME = 1, DRAME = 0) Software Standby Mode Signal &63 5' +:5 /:5 5)6+ SRFMD = 0 High High-impedance High-impedance High-impedance High SRFMD = 1 (Self-Refresh Mode) High High-impedance High-impedance High-impedance Low Rev. 2.0, 03/01, page 173 of 822 Software standby mode Address bus CS3 RD HWR LWR RFSH High High-impedance High-impedance High-impedance High-impedance Oscillator settling time Figure 7.16 Signal Output Timing in Self-Refresh Mode (PSRAME = 1, DRAME = 0) Operation in Power-Down State: The refresh controller operates in sleep mode. It does not operate in hardware standby mode. In software standby mode RTCNT is initialized, but RFSHCR, RTMCSR bits 5 to 3, and RTCOR retain their settings prior to the transition to software standby mode. Example: Pseudo-static RAM may have separate 2( and 5)6+ pins, or these may be combined into a single 2(/5)6+ pin. Figure 7.17 shows an example of a circuit for generating an 2(/5)6+ signal. Check the device characteristics carefully, and design a circuit that fits them. Figure 7.18 shows a setup procedure to be followed by a program. H8/3052F PSRAM RD OE / RFSH RFSH Figure 7.17 Interconnection to Pseudo-Static RAM with 2( 5)6+ Signal (Example) 2(/5)6+ Rev. 2.0, 03/01, page 174 of 822 Set P81 DDR to 1 for 3 output Set RTCOR Set bits CKS2 to CKS0 in RTMCSR Write H'47 in RFSHCR Wait for PSRAM to be initialized PSRAM can be accessed Figure 7.18 Setup Procedure for Pseudo-Static RAM Rev. 2.0, 03/01, page 175 of 822 7.3.4 Interval Timer To use the refresh controller as an interval timer, clear the PSRAME and DRAME both to 0. After setting RTCOR, select a clock source with bits CKS2 to CKS0 in RTMCSR, and set the CMIE bit to 1. Timing of Setting of Compare Match Flag and Clearing by Compare Match: The CMF flag in RTCSR is set to 1 by a compare match signal output when the RTCOR and RTCNT values match. The compare match signal is generated in the last state in which the values match (when RTCNT is updated from the matching value to a new value). Accordingly, when RTCNT and RTCOR match, the compare match signal is not generated until the next counter clock pulse. Figure 7.19 shows the timing. RTCNT N H'00 RTCOR Compare match signal CMF flag N Figure 7.19 Timing of Setting of CMF Flag Operation in Power-Down State: The interval timer function operates in sleep mode. It does not operate in hardware standby mode. In software standby mode RTCNT and RTMCSR bits 7 and 6 are initialized, but RTMCSR bits 5 to 3 and RTCOR retain their settings prior to the transition to software standby mode. Rev. 2.0, 03/01, page 176 of 822 Contention between RTCNT Write and Counter Clear: If a counter clear signal occurs in the T3 state of an RTCNT write cycle, clearing of the counter takes priority and the write is not performed. See figure 7.20. RTCNT write cycle by CPU T1 T2 T3 Address bus RTCNT address Internal write signal Counter clear signal RTCNT N H'00 Figure 7.20 Contention between RTCNT Write and Clear Rev. 2.0, 03/01, page 177 of 822 Contention between RTCNT Write and Increment: If an increment pulse occurs in the T3 state of an RTCNT write cycle, writing takes priority and RTCNT is not incremented. See figure 7.21. RTCNT write cycle by CPU T1 T2 T3 Address bus RTCNT address Internal write signal RTCNT input clock RTCNT N M Counter write data Figure 7.21 Contention between RTCNT Write and Increment Rev. 2.0, 03/01, page 178 of 822 Contention between RTCOR Write and Compare Match: If a compare match occurs in the T3 state of an RTCOR write cycle, writing takes priority and the compare match signal is inhibited. See figure 7.22. RTCOR write cycle by CPU T1 T2 T3 Address bus RTCNT address Internal write signal RTCNT N N+1 RTCOR N M RTCOR write data Compare match signal Inhibited Figure 7.22 Contention between RTCOR Write and Compare Match RTCNT Operation at Internal Clock Source Switchover: Switching internal clock sources may cause RTCNT to increment, depending on the switchover timing. Table 7.9 shows the relation between the time of the switchover (by writing to bits CKS2 to CKS0) and the operation of RTCNT. The RTCNT input clock is generated from the internal clock source by detecting the falling edge of the internal clock. If a switchover is made from a high clock source to a low clock source, as in case No. 3 in table 7.9, the switchover will be regarded as a falling edge, an RTCNT clock pulse will be generated, and RTCNT will be incremented. Rev. 2.0, 03/01, page 179 of 822 Table 7.9 No. 1 Internal Clock Switchover and RTCNT Operation RTCNT Operation Old clock source New clock source RTCNT clock CKS2 to CKS0 Write Timing Low low switchover*1 RTCNT N CKS bits rewritten N+1 2 Low high switchover* 2 Old clock source New clock source RTCNT clock RTCNT N N+1 N+2 CKS bits rewritten Rev. 2.0, 03/01, page 180 of 822 No. 3 CKS2 to CKS0 Write Timing High low switchover* 3 RTCNT Operation Old clock source New clock source RTCNT clock *4 RTCNT N N+1 CKS bits rewritten N+2 4 High high switchover Old clock source New clock source RTCNT clock RTCNT N N+1 N+2 CKS bits rewritten Notes: 1. Including switchovers from a low clock source to the halted state, and from the halted state to a low clock source. 2. Including switchover from the halted state to a high clock source. 3. Including switchover from a high clock source to the halted state. 4. The switchover is regarded as a falling edge, causing RTCNT to increment. Rev. 2.0, 03/01, page 181 of 822 7.4 Interrupt Source Compare match interrupts (CMI) can be generated when the refresh controller is used as an interval timer. Compare match interrupt requests are masked/unmasked with the CMIE bit of RTMCSR. 7.5 Usage Notes When using the DRAM or pseudo-static RAM refresh function, note the following points: With the refresh controller, if directly connected DRAM or PSRAM is disconnected*, the P80/5)6+/,540 pin and the P81/&63/,541 pin may both become low-level outputs simultaneously. Note: * When the DRAM enable bit (DRAME) or PSRAM enable bit (PSRAME) in the refresh control register (RFSHCR) is cleared to 0 after being set to 1. Address bus P80/ P81/ 3/ Area 3 start address 0 / 1 Figure 7.23 Operation when DRAM/PSRAM Connection is Switched Refresh cycles are not executed while the bus is released, during software standby mode, and when a bus cycle is greatly prolonged by insertion of wait states. When these conditions occur, other means of refreshing are required. If refresh requests occur while the bus is released, the first request is held and one refresh cycle is executed after the bus-released state ends. Figure 7.24 shows the bus cycles in this case. Rev. 2.0, 03/01, page 182 of 822 Bus-released state Refresh cycle CPU cycle Refresh cycle Refresh request Figure 7.24 Refresh Cycles when Bus is Released If a bus cycle is prolonged by insertion of wait states, the first refresh request is held, as in the busreleased state. If there is contention with a bus request from an external bus master when making a transition to software standby mode, a one-state bus-released state may occur immediately before the transition to software standby mode (see figure 7.25). When using software standby mode, clear the BRLE bit to 0 in BRCR before executing the SLEEP instruction. When making a transition to self-refresh mode, the strobe waveform output may not be guaranteed due to the same kind of contention. This, too, can be prevented by clearing the BRLE bit to 0 in BRCR. Rev. 2.0, 03/01, page 183 of 822 External bus released state Software standby mode Address bus Strobe Figure 7.25 Contention between Bus-Released State and Software Standby Mode Rev. 2.0, 03/01, page 184 of 822 Section 8 DMA Controller 8.1 Overview The H8/3052F has an on-chip DMA controller (DMAC) that can transfer data on up to four channels. When the DMA controller is not used, it can be independently halted to conserve power. For details see section 20.6, Module Standby Function. 8.1.1 Features DMAC features are listed below. * Selection of short address mode or full address mode Short address mode 8-bit source address and 24-bit destination address, or vice versa Maximum four channels available Selection of I/O mode, idle mode, or repeat mode Full address mode 24-bit source and destination addresses Maximum two channels available Selection of normal mode or block transfer mode * Directly addressable 16-Mbyte address space * Selection of byte or word transfer * Activation by internal interrupts, external requests, or auto-request (depending on transfer mode) 16-bit integrated timer unit (ITU) compare match/input capture interrupts (four) Serial communication interface (SCI channel 0) transmit-data-empty/receive-data-full interrupts External requests Auto-request Rev. 2.0, 03/01, page 185 of 822 8.1.2 Block Diagram Figure 8.1 shows a DMAC block diagram. Internal address bus Internal interrupts IMIA0 IMIA1 IMIA2 IMIA3 TXI0 RXI0 Control logic Channel 0 Address buffer Arithmetic-logic unit MAR0A Channel 0A IOAR0A Module data bus ETCR0A MAR0B Channel 0B IOAR0B ETCR0B MAR1A Channel 1A IOAR1A ETCR1A MAR1B Channel 1B IOAR1B ETCR1B DTCR0A Interrupt DEND0A DEND0B signals DEND1A DEND1B DTCR0B DTCR1A DTCR1B Channel 1 Data buffer Internal data bus Legend DTCR: Data transfer control register MAR: Memory address register IOAR: I/O address register ETCR: Execute transfer count register Figure 8.1 Block Diagram of DMAC Rev. 2.0, 03/01, page 186 of 822 8.1.3 Functional Overview Table 8.1 gives an overview of the DMAC functions. Table 8.1 DMAC Functional Overview Address Reg. Length Transfer Mode Short address mode I/O mode * * * Transfers one byte or one word per request Increments or decrements the memory address by 1 or 2 Executes 1 to 65,536 transfers * * Activation * Compare match/ input capture A interrupts from ITU channels 0 to 3 Transmit-data-empty interrupt from SCI channel 0 Receive-data-full interrupt from SCI channel 0 External request 8 24 Source 24 Destination 8 Idle mode * * * Transfers one byte or one word per request Holds the memory address fixed Executes 1 to 65,536 transfers * 24 8 Repeat mode * * * Transfers one byte or one word per request Increments or decrements the memory address by 1 or 2 Executes a specified number (1 to 255) of transfers, then returns to the initial state and continues Rev. 2.0, 03/01, page 187 of 822 Address Reg. Length Transfer Mode Full address mode Normal mode * Auto-request Retains the transfer request internally Executes a specified number (1 to 65,536) of transfers continuously Selection of burst mode or cycle-steal mode * External request Transfers one byte or one word per request Executes 1 to 65,536 transfers Block transfer * * * Transfers one block of a specified size per request Executes 1 to 65,536 transfers Allows either the source or destination to be a fixed block area Block size can be 1 to 255 bytes or words * * Compare match/ input capture A interrupts from ITU channels 0 to 3 External request 24 24 Activation * * Auto-request External request Source 24 Destination 24 * Rev. 2.0, 03/01, page 188 of 822 8.1.4 Pin Configuration Table 8.2 lists the DMAC pins. Table 8.2 Channel 0 1 DMAC Pins Name DMA request 0 Transfer end 0 DMA request 1 Transfer end 1 Abbreviation '5(40 7(1'0 '5(41 7(1'1 Input/ Output Input Output Input Output Function External request for DMAC channel 0 Transfer end on DMAC channel 0 External request for DMAC channel 1 Transfer end on DMAC channel 1 Note: External requests cannot be made to channel A in short address mode. 8.1.5 Register Configuration Table 8.3 lists the DMAC registers. Rev. 2.0, 03/01, page 189 of 822 Table 8.3 Channel 0 DMAC Registers Address* H'FF20 H'FF21 H'FF22 H'FF23 H'FF26 H'FF24 H'FF25 H'FF27 H'FF28 H'FF29 H'FF2A H'FF2B H'FF2E H'FF2C H'FF2D H'FF2F Name Memory address register 0AR Memory address register 0AE Memory address register 0AH Memory address register 0AL I/O address register 0A Execute transfer count register 0AH Execute transfer count register 0AL Data transfer control register 0A Memory address register 0BR Memory address register 0BE Memory address register 0BH Memory address register 0BL I/O address register 0B Execute transfer count register 0BH Execute transfer count register 0BL Data transfer control register 0B Memory address register 1AR Memory address register 1AE Memory address register 1AH Memory address register 1AL I/O address register 1A Execute transfer count register 1AH Execute transfer count register 1AL Data transfer control register 1A Memory address register 1BR Memory address register 1BE Memory address register 1BH Memory address register 1BL I/O address register 1B Execute transfer count register 1BH Execute transfer count register 1BL Data transfer control register 1B Abbreviation MAR0AR MAR0AE MAR0AH MAR0AL IOAR0A ETCR0AH ETCR0AL DTCR0A MAR0BR MAR0BE MAR0BH MAR0BL IOAR0B ETCR0BH ETCR0BL DTCR0B MAR1AR MAR1AE MAR1AH MAR1AL IOAR1A ETCR1AH ETCR1AL DTCR1A MAR1BR MAR1BE MAR1BH MAR1BL IOAR1B ETCR1BH ETCR1BL DTCR1B R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Initial Value Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined H'00 Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined H'00 Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined H'00 Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined Undetermined H'00 1 H'FF30 H'FF31 H'FF32 H'FF33 H'FF36 H'FF34 H'FF35 H'FF37 H'FF38 H'FF39 H'FF3A H'FF3B H'FF3E H'FF3C H'FF3D H'FF3F Note: * The lower 16 bits of the address are indicated. Rev. 2.0, 03/01, page 190 of 822 8.2 Register Descriptions (Short Address Mode) In short address mode, transfers can be carried out independently on channels A and B. Short address mode is selected by bits DTS2A and DTS1A in data transfer control register A (DTCRA) as indicated in table 8.4. Table 8.4 Channel 0 Selection of Short and Full Address Modes Bit 2: DTS2A 1 Bit 1: DTS1A 1 Description DMAC channel 0 operates as one channel in full address mode DMAC channels 0A and 0B operate as two independent channels in short address mode DMAC channel 1 operates as one channel in full address mode DMAC channels 1A and 1B operate as two independent channels in short address mode Other than above 1 1 1 Other than above Rev. 2.0, 03/01, page 191 of 822 8.2.1 Memory Address Registers (MAR) A memory address register (MAR) is a 32-bit readable/writable register that specifies a source or destination address. The transfer direction is determined automatically from the activation source. An MAR consists of four 8-bit registers designated MARR, MARE, MARH, and MARL. All bits of MARR are reserved: they cannot be modified and always return an undetermined value when read. Bit Initial value Read/Write -- -- 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 Undetermined -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MARE MARR Source or destination address Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MARH Source or destination address MARL An MAR functions as a source or destination address register depending on how the DMAC is activated: as a destination address register if activation is by a receive-data-full interrupt from the serial communication interface (SCI) (channel 0), and as a source address register otherwise. The MAR value is incremented or decremented each time one byte or word is transferred, automatically updating the source or destination memory address. For details, see section 8.2.4, Data Transfer Control Registers (DTCR). The MARs are not initialized by a reset or in standby mode. Rev. 2.0, 03/01, page 192 of 822 8.2.2 I/O Address Registers (IOAR) An I/O address register (IOAR) is an 8-bit readable/writable register that specifies a source or destination address. The IOAR value is the lower 8 bits of the address. The upper 16 address bits are all 1 (H'FFFF). Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W Source or destination address An IOAR functions as a source or destination address register depending on how the DMAC is activated: as a source address register if activation is by a receive-data-full interrupt from the SCI (channel 0), and as a destination address register otherwise. The IOAR value is held fixed. It is not incremented or decremented when a transfer is executed. The IOARs are not initialized by a reset or in standby mode. Rev. 2.0, 03/01, page 193 of 822 8.2.3 Execute Transfer Count Registers (ETCR) An execute transfer count register (ETCR) is a 16-bit readable/writable register that specifies the number of transfers to be executed. These registers function in one way in I/O mode and idle mode, and another way in repeat mode. * I/O mode and idle mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Transfer counter In I/O mode and idle mode, ETCR functions as a 16-bit counter. The count is decremented by 1 each time one transfer is executed. The transfer ends when the count reaches H'0000. * Repeat mode Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCRH Transfer counter Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCRL Initial count In repeat mode, ETCRH functions as an 8-bit transfer counter and ETCRL holds the initial transfer count. ETCRH is decremented by 1 each time one transfer is executed. When ETCRH reaches H'00, the value in ETCRL is reloaded into ETCRH and the same operation is repeated. The ETCRs are not initialized by a reset or in standby mode. Rev. 2.0, 03/01, page 194 of 822 8.2.4 Data Transfer Control Registers (DTCR) A data transfer control register (DTCR) is an 8-bit readable/writable register that controls the operation of one DMAC channel. Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 DTID 0 R/W 4 RPE 0 R/W 3 DTIE 0 R/W 2 DTS2 0 R/W 1 DTS1 0 R/W 0 DTS0 0 R/W Data transfer enable Enables or disables data transfer Data transfer size Selects byte or word size Data transfer increment/decrement Selects whether to increment or decrement the memory address register Repeat enable Selects repeat mode Data transfer select These bits select the data transfer activation source Data transfer interrupt enable Enables or disables the CPU interrupt at the end of the transfer The DTCRs are initialized to H'00 by a reset and in standby mode. Bit 7--Data Transfer Enable (DTE): Enables or disables data transfer on a channel. When the DTE bit is set to 1, the channel waits for a transfer to be requested, and executes the transfer when activated as specified by bits DTS2 to DTS0. When DTE is 0, the channel is disabled and does not accept transfer requests. DTE is set to 1 by reading the register when DTE is 0, then writing 1. Bit 7: DTE 0 1 Description Data transfer is disabled. In I/O mode or idle mode, DTE is cleared to 0 when the specified number of transfers have been completed. (Initial value) Data transfer is enabled If DTIE is set to 1, a CPU interrupt is requested when DTE is cleared to 0. Rev. 2.0, 03/01, page 195 of 822 Bit 6--Data Transfer Size (DTSZ): Selects the data size of each transfer. Bit 6: DTSZ 0 1 Description Byte-size transfer Word-size transfer (Initial value) Bit 5--Data Transfer Increment/Decrement (DTID): Selects whether to increment or decrement the memory address register (MAR) after a data transfer in I/O mode or repeat mode. Bit 5: DTID 0 Description MAR is incremented after each data transfer * * 1 If DTSZ = 0, MAR is incremented by 1 after each transfer If DTSZ = 1, MAR is incremented by 2 after each transfer MAR is decremented after each data transfer * * If DTSZ = 0, MAR is decremented by 1 after each transfer If DTSZ = 1, MAR is decremented by 2 after each transfer MAR is not incremented or decremented in idle mode. Bit 4--Repeat Enable (RPE): Selects whether to transfer data in I/O mode, idle mode, or repeat mode. Bit 4: RPE 0 1 Bit 3: DTIE 0 1 0 1 Repeat mode Idle mode Description I/O mode (Initial value) Operations in these modes are described in sections 8.4.2, I/O Mode, 8.4.3, Idle Mode, and 8.4.4, Repeat Mode. Bit 3--Data Transfer Interrupt Enable (DTIE): Enables or disables the CPU interrupt (DEND) requested when the DTE bit is cleared to 0. Bit 3: DTIE 0 1 Description The DEND interrupt requested by DTE is disabled The DEND interrupt requested by DTE is enabled (Initial value) Rev. 2.0, 03/01, page 196 of 822 Bits 2 to 0--Data Transfer Select (DTS2, DTS1, DTS0): These bits select the data transfer activation source. Some of the selectable sources differ between channels A and B. Note: Refer to 8.3.4, Data Transfer Control Registers (DTCR). Bit 2: DTS2 0 Bit 1: DTS1 0 Bit 0: DTS0 0 1 1 0 1 1 0 1 0 1 0 1 Description Compare match/input capture A interrupt from ITU channel 0 (Initial value) Compare match/input capture A interrupt from ITU channel 1 Compare match/input capture A interrupt from ITU channel 2 Compare match/input capture A interrupt from ITU channel 3 Transmit-data-empty interrupt from SCI channel 0 Receive-data-full interrupt from SCI channel 0 Falling edge of DREQ input (channel B) Transfer in full address mode (channel A) Low level of DREQ input (channel B) Transfer in full address mode (channel A) The same internal interrupt can be selected as an activation source for two or more channels at once. In that case the channels are activated in a priority order, highest-priority channel first. For the priority order, see section 8.4.9, Multiple-Channel Operation. When a channel is enabled (DTE = 1), its selected DMAC activation source cannot generate a CPU interrupt. Rev. 2.0, 03/01, page 197 of 822 8.3 Register Descriptions (Full Address Mode) In full address mode the A and B channels operate together. Full address mode is selected as indicated in table 8.4. 8.3.1 Memory Address Registers (MAR) A memory address register (MAR) is a 32-bit readable/writable register. MARA functions as the source address register of the transfer, and MARB as the destination address register. An MAR consists of four 8-bit registers designated MARR, MARE, MARH, and MARL. All bits of MARR are reserved: they cannot be modified and always return an undetermined value when read. Bit Initial value Read/Write -- -- 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 Undetermined -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MARE MARR Source or destination address Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MARH Source or destination address MARL The MAR value is incremented or decremented each time one byte or word is transferred, automatically updating the source or destination memory address. For details, see section 8.3.4, Data Transfer Control Registers (DTCR). The MARs are not initialized by a reset or in standby mode. Rev. 2.0, 03/01, page 198 of 822 8.3.2 I/O Address Registers (IOAR) The I/O address registers (IOARs) are not used in full address mode. 8.3.3 Execute Transfer Count Registers (ETCR) An execute transfer count register (ETCR) is a 16-bit readable/writable register that specifies the number of transfers to be executed. The functions of these registers differ between normal mode and block transfer mode. * Normal mode ETCRA Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Transfer counter ETCRB: Is not used in normal mode. In normal mode ETCRA functions as a 16-bit transfer counter. The count is decremented by 1 each time one transfer is executed. The transfer ends when the count reaches H'0000. ETCRB is not used. Rev. 2.0, 03/01, page 199 of 822 * Block transfer mode ETCRA Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCRAH Block size counter Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCRAL Initial block size ETCRB Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Block transfer counter In block transfer mode, ETCRAH functions as an 8-bit block size counter. ETCRAL holds the initial block size. ETCRAH is decremented by 1 each time one byte or word is transferred. When the count reaches H'00, ETCRAH is reloaded from ETCRAL. Blocks consisting of an arbitrary number of bytes or words can be transferred repeatedly by setting the same initial block size value in ETCRAH and ETCRAL. In block transfer mode ETCRB functions as a 16-bit block transfer counter. ETCRB is decremented by 1 each time one block is transferred. The transfer ends when the count reaches H'0000. The ETCRs are not initialized by a reset or in standby mode. Rev. 2.0, 03/01, page 200 of 822 8.3.4 Data Transfer Control Registers (DTCR) The data transfer control registers (DTCRs) are 8-bit readable/writable registers that control the operation of the DMAC channels. A channel operates in full address mode when bits DTS2A and DTS1A are both set to 1 in DTCRA. DTCRA and DTCRB have different functions in full address mode. DTCRA Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 SAID 0 R/W 4 SAIDE 0 R/W 3 DTIE 0 R/W 2 DTS2A 0 R/W 1 DTS1A 0 R/W 0 DTS0A 0 R/W Data transfer enable Enables or disables data transfer Data transfer size Selects byte or word size Data transfer interrupt enable Enables or disables the CPU interrupt at the end of the transfer Data transfer select 0A Selects block transfer mode Source address increment/decrement Source address increment/ decrement enable These bits select whether the source address register (MARA) is incremented, decremented, or held fixed during the data transfer Data transfer select 2A and 1A These bits must both be set to 1 DTCRA is initialized to H'00 by a reset and in standby mode. Bit 7--Data Transfer Enable (DTE): Together with the DTME bit in DTCRB, this bit enables or disables data transfer on the channel. When the DTME and DTE bits are both set to 1, the channel is enabled. If auto-request is specified, data transfer begins immediately. Otherwise, the channel waits for transfers to be requested. When the specified number of transfers have been completed, the DTE bit is automatically cleared to 0. When DTE is 0, the channel is disabled and does not accept transfer requests. DTE is set to 1 by reading the register when DTE is 0, then writing 1. Bit 7: DTE 0 1 Description Data transfer is disabled (DTE is cleared to 0 when the specified number of transfers have been completed) (Initial value) Data transfer is enabled Rev. 2.0, 03/01, page 201 of 822 If DTIE is set to 1, a CPU interrupt is requested when DTE is cleared to 0. Bit 6--Data Transfer Size (DTSZ): Selects the data size of each transfer. Bit 6: DTSZ 0 1 Description Byte-size transfer Word-size transfer (Initial value) Bit 5--Source Address Increment/Decrement (SAID) and Bit 4--Source Address Increment/Decrement Enable (SAIDE): These bits select whether the source address register (MARA) is incremented, decremented, or held fixed during the data transfer. Bit 5: SAID 0 Bit 4: SAIDE 0 1 Description MARA is held fixed * * (Initial value) MARA is incremented after each data transfer If DTSZ = 0, MARA is incremented by 1 after each transfer If DTSZ = 1, MARA is incremented by 2 after each transfer 1 0 1 MARA is held fixed MARA is decremented after each data transfer * * If DTSZ = 0, MARA is decremented by 1 after each transfer If DTSZ = 1, MARA is decremented by 2 after each transfer Bit 3--Data Transfer Interrupt Enable (DTIE): Enables or disables the CPU interrupt (DEND) requested when the DTE bit is cleared to 0. Bit 3: DTIE 0 1 Description The DEND interrupt requested by DTE is disabled The DEND interrupt requested by DTE is enabled (Initial value) Bits 2 and 1--Data Transfer Select 2A and 1A (DTS2A, DTS1A): A channel operates in full address mode when DTS2A and DTS1A are both set to 1. Bit 0--Data Transfer Select 0A (DTS0A): Selects normal mode or block transfer mode. Bit 0: DTS0A 0 1 Description Normal mode Block transfer mode (Initial value) Rev. 2.0, 03/01, page 202 of 822 Operations in these modes are described in sections 8.4.5, Normal Mode, and 8.4.6, Block Transfer Mode. DTCRB Bit Initial value Read/Write 7 DTME 0 R/W 6 -- 0 R/W 5 DAID 0 R/W 4 DAIDE 0 R/W 3 TMS 0 R/W 2 DTS2B 0 R/W 1 DTS1B 0 R/W 0 DTS0B 0 R/W Data transfer master enable Enables or disables data transfer, together with the DTE bit, and is cleared to 0 by an interrupt Reserved bit Transfer mode select Selects whether the block area is the source or destination in block transfer mode Data transfer select 2B to 0B These bits select the data transfer activation source Destination address increment/decrement Destination address increment/decrement enable These bits select whether the destination address register (MARB) is incremented, decremented, or held fixed during the data transfer DTCRB is initialized to H'00 by a reset and in standby mode. Bit 7--Data Transfer Master Enable (DTME): Together with the DTE bit in DTCRA, this bit enables or disables data transfer. When the DTME and DTE bits are both set to 1, the channel is enabled. When an NMI interrupt occurs DTME is cleared to 0, suspending the transfer so that the CPU can use the bus. The suspended transfer resumes when DTME is set to 1 again. For further information on operation in block transfer mode, see section 8.6.6, NMI Interrupts and Block Transfer Mode. DTME is set to 1 by reading the register while DTME = 0, then writing 1. Bit 7: DTME 0 1 Description Data transfer is disabled (DTME is cleared to 0 when an NMI interrupt occurs) (Initial value) Data transfer is enabled Rev. 2.0, 03/01, page 203 of 822 Bit 6--Reserved: Although reserved, this bit can be written and read. Bit 5--Destination Address Increment/Decrement (DAID) and Bit 4--Destination Address Increment/Decrement Enable (DAIDE): These bits select whether the destination address register (MARB) is incremented, decremented, or held fixed during the data transfer. Bit 5: DAID 0 Bit 4: DAIDE 0 1 Description MARB is held fixed * * (Initial value) MARB is incremented after each data transfer If DTSZ = 0, MARB is incremented by 1 after each data transfer If DTSZ = 1, MARB is incremented by 2 after each data transfer 1 0 1 MARB is held fixed MARB is decremented after each data transfer * * If DTSZ = 0, MARB is decremented by 1 after each data transfer If DTSZ = 1, MARB is decremented by 2 after each data transfer Bit 3--Transfer Mode Select (TMS): Selects whether the source or destination is the block area in block transfer mode. Bit 3: TMS 0 1 Description Destination is the block area in block transfer mode Source is the block area in block transfer mode (Initial value) Rev. 2.0, 03/01, page 204 of 822 Bits 2 to 0--Data Transfer Select 2B to 0B (DTS2B, DTS1B, DTS0B): These bits select the data transfer activation source. The selectable activation sources differ between normal mode and block transfer mode. * Normal mode Bit 2: DTS2B 0 Bit 1: DTS1B 0 1 1 0 1 Bit 0: DTS0B 0 1 0 1 0 1 0 1 Description Auto-request (burst mode) Cannot be used Auto-request (cycle-steal mode) Cannot be used Cannot be used Cannot be used Falling edge of '5(4 Low level input at '5(4 (Initial value) * Block transfer mode Bit 2: DTS2B 0 Bit 1: DTS1B 0 Bit 0: DTS0B 0 1 1 0 1 1 0 1 0 1 0 1 Description Compare match/input capture A interrupt from ITU channel 0 (Initial value) Compare match/input capture A interrupt from ITU channel 1 Compare match/input capture A interrupt from ITU channel 2 Compare match/input capture A interrupt from ITU channel 3 Cannot be used Cannot be used Falling edge of '5(4 Cannot be used The same internal interrupt can be selected to activate two or more channels. The channels are activated in a priority order, highest priority first. For the priority order, see section 8.4.9, DMAC Multiple-Channel Operation. Rev. 2.0, 03/01, page 205 of 822 8.4 8.4.1 Operation Overview Table 8.5 summarizes the DMAC modes. Table 8.5 DMAC Modes Activation I/O mode Idle mode Repeat mode Compare match/input capture A interrupt from ITU channels 0 to 3 Transmit-data-empty and receive-data-full interrupts from SCI channel 0 External request Full address mode Normal mode Block transfer mode Auto-request External request Compare match/input capture A interrupt from ITU * channels 0 to 3 External request * A and B channels are paired; up to two channels are available Burst mode or cycle-steal mode can be selected for auto-requests Notes * * Up to four channels can operate independently Only the B channels support external requests Transfer Mode Short address mode A summary of operations in these modes follows. I/O Mode: One byte or word is transferred per request. A designated number of these transfers are executed. A CPU interrupt can be requested at completion of the designated number of transfers. One 24-bit address and one 8-bit address are specified. The transfer direction is determined automatically from the activation source. Idle Mode: One byte or word is transferred per request. A designated number of these transfers are executed. A CPU interrupt can be requested at completion of the designated number of transfers. One 24-bit address and one 8-bit address are specified. The addresses are held fixed. The transfer direction is determined automatically from the activation source. Repeat Mode: One byte or word is transferred per request. A designated number of these transfers are executed. When the designated number of transfers are completed, the initial address and counter value are restored and operation continues. No CPU interrupt is requested. One 24-bit address and one 8-bit address are specified. The transfer direction is determined automatically from the activation source. Rev. 2.0, 03/01, page 206 of 822 Normal Mode * Auto-request The DMAC is activated by register setup alone, and continues executing transfers until the designated number of transfers have been completed. A CPU interrupt can be requested at completion of the transfers. Both addresses are 24-bit addresses. Cycle-steal mode The bus is released to another bus master after each byte or word is transferred. Burst mode Unless requested by a higher-priority bus master, the bus is not released until the designated number of transfers have been completed. * External request One byte or word is transferred per request. A designated number of these transfers are executed. A CPU interrupt can be requested at completion of the designated number of transfers. Both addresses are 24-bit addresses. Block Transfer Mode: One block of a specified size is transferred per request. A designated number of block transfers are executed. At the end of each block transfer, one address is restored to its initial value. When the designated number of blocks have been transferred, a CPU interrupt can be requested. Both addresses are 24-bit addresses. Rev. 2.0, 03/01, page 207 of 822 8.4.2 I/O Mode I/O mode can be selected independently for each channel. One byte or word is transferred at each transfer request in I/O mode. A designated number of these transfers are executed. One address is specified in the memory address register (MAR), the other in the I/O address register (IOAR). The direction of transfer is determined automatically from the activation source. The transfer is from the address specified in IOAR to the address specified in MAR if activated by an SCI channel 0 receive-data-full interrupt, and from the address specified in MAR to the address specified in IOAR otherwise. Table 8.6 indicates the register functions in I/O mode. Table 8.6 Register Functions in I/O Mode Function Activated by SCI 0 ReceiveData-Full Other Interrupt Activation 0 MAR Register 23 Initial Setting Destination or source address Operation Incremented or decremented once per transfer Held fixed Destination address register Source address register Transfer counter Source address register Destination address register Transfer counter 23 All 1s 7 IOAR 0 Source or destination address Number of transfers 15 ETCR 0 Decremented once per transfer until H'0000 is reached and transfer ends Legend MAR: Memory address register IOAR: I/O address register ETCR: Execute transfer count register MAR and IOAR specify the source and destination addresses. MAR specifies a 24-bit source or destination address, which is incremented or decremented as each byte or word is transferred. IOAR specifies the lower 8 bits of a fixed address. The upper 16 bits are all 1s. IOAR is not incremented or decremented. Figure 8.2 illustrates how I/O mode operates. Rev. 2.0, 03/01, page 208 of 822 Address T Transfer IOAR 1 byte or word is transferred per request Address B Legend L = initial setting of MAR N = initial setting of ETCR Address T = L Address B = L + (-1) DTID (2 DTSZ N - 1) Figure 8.2 Operation in I/O Mode The transfer count is specified as a 16-bit value in ETCR. The ETCR value is decremented by 1 at each transfer. When the ETCR value reaches H'0000, the DTE bit is cleared and the transfer ends. If the DTIE bit is set to 1, a CPU interrupt is requested at this time. The maximum transfer count is 65,536, obtained by setting ETCR to H'0000. Transfers can be requested (activated) by compare match/input capture A interrupts from ITU channels 0 to 3, transmit-data-empty and receive-data-full interrupts from SCI channel 0, and external request signals. For the detailed settings see section 8.2.4, Data Transfer Control Registers (DTCR). Rev. 2.0, 03/01, page 209 of 822 Figure 8.3 shows a sample setup procedure for I/O mode. I/O mode setup Set source and destination addresses 1. Set the source and destination addresses in MAR and IOAR. The transfer direction is determined automatically from the activation source. 1 2. Set the transfer count in ETCR. 3. Read DTCR while the DTE bit is cleared to 0. Set transfer count 2 Read DTCR 3 Set DTCR 4 I/O mode 4. Set the DTCR bits as follows. * Select the DMAC activation source with bits DTS2 to DTS0. * Set or clear the DTIE bit to enable or disable the CPU interrupt at the end of the transfer. * Clear the RPE bit to 0 to select I/O mode. * Select MAR increment or decrement with the DTID bit. * Select byte size or word size with the DTSZ bit. * Set the DTE bit to 1 to enable the transfer. Figure 8.3 I/O Mode Setup Procedure (Example) 8.4.3 Idle Mode Idle mode can be selected independently for each channel. One byte or word is transferred at each transfer request in idle mode. A designated number of these transfers are executed. One address is specified in the memory address register (MAR), the other in the I/O address register (IOAR). The direction of transfer is determined automatically from the activation source. The transfer is from the address specified in IOAR to the address specified in MAR if activated by an SCI channel 0 receive-data-full interrupt, and from the address specified in MAR to the address specified in IOAR otherwise. Table 8.7 indicates the register functions in idle mode. Rev. 2.0, 03/01, page 210 of 822 Table 8.7 Register Functions in Idle Mode Function Activated by SCI 0 ReceiveData-Full Other Interrupt Activation 0 MAR Register 23 Initial Setting Destination or source address Source or destination address Number of transfers Operation Held fixed Destination address register Source address register Transfer counter Source address register Destination address register Transfer counter 23 All 1s 7 IOAR 0 Held fixed 15 ETCR 0 Decremented once per transfer until H'0000 is reached and transfer ends Legend MAR: Memory address register IOAR: I/O address register ETCR: Execute transfer count register MAR and IOAR specify the source and destination addresses. MAR specifies a 24-bit source or destination address. IOAR specifies the lower 8 bits of a fixed address. The upper 16 bits are all 1s. MAR and IOAR are not incremented or decremented. Figure 8.4 illustrates how idle mode operates. MAR Transfer IOAR 1 byte or word is transferred per request Figure 8.4 Operation in Idle Mode Rev. 2.0, 03/01, page 211 of 822 The transfer count is specified as a 16-bit value in ETCR. The ETCR value is decremented by 1 at each transfer. When the ETCR value reaches H'0000, the DTE bit is cleared, the transfer ends, and a CPU interrupt is requested. The maximum transfer count is 65,536, obtained by setting ETCR to H'0000. Transfers can be requested (activated) by compare match/input capture A interrupts from ITU channels 0 to 3, transmit-data-empty and receive-data-full interrupts from SCI channel 0, and external request signals. For the detailed settings see section 8.2.4, Data Transfer Control Registers (DTCR). Figure 8.5 shows a sample setup procedure for idle mode. Idle mode setup Set source and destination addresses 1 1. Set the source and destination addresses in MAR and IOAR. The transfer direction is determined automatically from the activation source. 2. Set the transfer count in ETCR. 3. Read DTCR while the DTE bit is cleared to 0. Set transfer count 2 Read DTCR 3 4. Set the DTCR bits as follows. * Select the DMAC activation source with bits DTS2 to DTS0. * Set the DTIE and RPE bits to 1 to select idle mode. * Select byte size or word size with the DTSZ bit. * Set the DTE bit to 1 to enable the transfer. Set DTCR 4 Idle mode Figure 8.5 Idle Mode Setup Procedure (Example) Rev. 2.0, 03/01, page 212 of 822 8.4.4 Repeat Mode Repeat mode is useful for cyclically transferring a bit pattern from a table to the programmable timing pattern controller (TPC) in synchronization, for example, with ITU compare match. Repeat mode can be selected for each channel independently. One byte or word is transferred per request in repeat mode, as in I/O mode. A designated number of these transfers are executed. One address is specified in the memory address register (MAR), the other in the I/O address register (IOAR). At the end of the designated number of transfers, MAR and ETCR are restored to their original values and operation continues. The direction of transfer is determined automatically from the activation source. The transfer is from the address specified in IOAR to the address specified in MAR if activated by an SCI channel 0 receive-datafull interrupt, and from the address specified in MAR to the address specified in IOAR otherwise. Table 8.8 indicates the register functions in repeat mode. Rev. 2.0, 03/01, page 213 of 822 Table 8.8 Register Functions in Repeat Mode Function Activated by SCI 0 ReceiveData-Full Interrupt Destination address register Register Other Activation Source address register Initial Setting Destination or source address Operation Incremented or decremented at each transfer until H'0000, then restored to initial value Held fixed 23 MAR 0 23 All 1s 7 IOAR 0 Source address register Transfer counter Destination address register Transfer counter Source or destination address Number of transfers 7 0 ETCRH Decremented once per transfer until H'0000 is reached, then reloaded from ETCRL Held fixed 7 0 ETCRL Initial transfer count Initial transfer Number of count transfers Legend MAR: Memory address register IOAR: I/O address register ETCR: Execute transfer count register In repeat mode ETCRH is used as the transfer counter while ETCRL holds the initial transfer count. ETCRH is decremented by 1 at each transfer until it reaches H'00, then is reloaded from ETCRL. MAR is also restored to its initial value, which is calculated from the DTSZ and DTID bits in DTCR. Specifically, MAR is restored as follows: MAR MAR - (-1)DTID * 2DTSZ * ETCRL ETCRH and ETCRL should be initially set to the same value. In repeat mode transfers continue until the CPU clears the DTE bit to 0. After DTE is cleared to 0, if the CPU sets DTE to 1 again, transfers resume from the state at which DTE was cleared. No CPU interrupt is requested. Rev. 2.0, 03/01, page 214 of 822 As in I/O mode, MAR and IOAR specify the source and destination addresses. MAR specifies a 24-bit source or destination address. IOAR specifies the lower 8 bits of a fixed address. The upper 16 bits are all 1s. IOAR is not incremented or decremented. Figure 8.6 illustrates how repeat mode operates. Address T Transfer IOAR 1 byte or word is transferred per request Address B Legend L = initial setting of MAR N = initial setting of ETCRH and ETCRL Address T = L Address B = L + (-1) DTID (2 DTSZ N - 1) * * Figure 8.6 Operation in Repeat Mode The transfer count is specified as an 8-bit value in ETCRH and ETCRL. The maximum transfer count is 255, obtained by setting both ETCRH and ETCRL to H'FF. Transfers can be requested (activated) by compare match/input capture A interrupts from ITU channels 0 to 3, transmit-data-empty and receive-data-full interrupts from SCI channel 0, and external request signals. For the detailed settings see section 8.2.4, Data Transfer Control Registers (DTCR). Figure 8.7 shows a sample setup procedure for repeat mode. Rev. 2.0, 03/01, page 215 of 822 Repeat mode Set source and destination addresses 1. Set the source and destination addresses in MAR and IOAR. The transfer direction is determined automatically from the activation source. 1 2. Set the transfer count in both ETCRH and ETCRL. 3. Read DTCR while the DTE bit is cleared to 0. 4. Set the DTCR bits as follows. * Select the DMAC activation source with bits DTS2 to DTS0. * Clear the DTIE bit to 0 and set the RPE bit to 1 to select repeat mode. * Select MAR increment or decrement with the DTID bit. * Select byte size or word size with the DTSZ bit. * Set the DTE bit to 1 to enable the transfer. Set transfer count 2 Read DTCR 3 Set DTCR 4 Repeat mode Figure 8.7 Repeat Mode Setup Procedure (Example) Rev. 2.0, 03/01, page 216 of 822 8.4.5 Normal Mode In normal mode the A and B channels are combined. One byte or word is transferred per request. A designated number of these transfers are executed. Addresses are specified in MARA and MARB. Table 8.9 indicates the register functions in I/O mode. Table 8.9 Register 23 MARA 23 MARB 0 0 Register Functions in Normal Mode Function Source address register Destination address register Transfer counter Initial Setting Source address Operation Incremented or decremented once per transfer, or held fixed Incremented or decremented once per transfer, or held fixed Decremented once per transfer Destination address Number of transfers 15 ETCRA 0 Legend MARA: Memory address register A MARB: Memory address register B ETCRA: Execute transfer count register A The source and destination addresses are both 24-bit addresses. MARA specifies the source address. MARB specifies the destination address. MARA and MARB can be independently incremented, decremented, or held fixed as data is transferred. The transfer count is specified as a 16-bit value in ETCRA. The ETCRA value is decremented by 1 at each transfer. When the ETCRA value reaches H'0000, the DTE bit is cleared and the transfer ends. If the DTIE bit is set, a CPU interrupt is requested at this time. The maximum transfer count is 65,536, obtained by setting ETCRA to H'0000. Figure 8.8 illustrates how normal mode operates. Rev. 2.0, 03/01, page 217 of 822 Address TA Transfer Address T B Address BA Address B B Legend L A = initial setting of MARA L B = initial setting of MARB N = initial setting of ETCRA TA = LA BA = L A + SAIDE (-1) SAID (2 TB = LB BB = L B + DAIDE (-1) DAID (2 * * * * DTSZ DTSZ * N - 1) N - 1) * Figure 8.8 Operation in Normal Mode Transfers can be requested (activated) by an external request or auto-request. An auto-requested transfer is activated by the register settings alone. The designated number of transfers are executed automatically. Either cycle-steal or burst mode can be selected. In cycle-steal mode the DMAC releases the bus temporarily after each transfer. In burst mode the DMAC keeps the bus until the transfers are completed, unless there is a bus request from a higher-priority bus master. For the detailed settings see section 8.3.4, Data Transfer Control Registers (DTCR). Rev. 2.0, 03/01, page 218 of 822 Figure 8.9 shows a sample setup procedure for normal mode. Normal mode 1. Set the initial source address in MARA. 2. Set the initial destination address in MARB. Set initial source address 1 3. Set the transfer count in ETCRA. 4. Set the DTCRB bits as follows. * Clear the DTME bit to 0. * Set the DAID and DAIDE bits to select whether * MARB is incremented, decremented, or held fixed. * Select the DMAC activation source with bits * DTS2B to DTS0B. 5. Set the DTCRA bits as follows. * Clear the DTE bit to 0. * Select byte or word size with the DTSZ bit. * Set the SAID and SAIDE bits to select whether MARA is incremented, decremented, or held fixed. * Set or clear the DTIE bit to enable or disable the CPU interrupt at the end of the transfer. * Clear the DTS0A bit to 0 and set the DTS2A and DTS1A bits to 1 to select normal mode. 6. Read DTCRB with DTME cleared to 0. Set initial destination address 2 Set transfer count 3 Set DTCRB (1) 4 Set DTCRA (1) 5 Read DTCRB 6 Set DTCRB (2) 7 Read DTCRA 8 7. Set the DTME bit to 1 in DTCRB. 8. Read DTCRA with DTE cleared to 0. Set DTCRA (2) 9 9. Set the DTE bit to 1 in DTCRA to enable the transfer. Normal mode Note: Carry out settings 1 to 9 with the DEND interrupt masked in the CPU. If an NMI interrupt occurs during the setup procedure, it may clear the DTME bit to 0, in which case the transfer will not start. Figure 8.9 Normal Mode Setup Procedure (Example) Rev. 2.0, 03/01, page 219 of 822 8.4.6 Block Transfer Mode In block transfer mode the A and B channels are combined. One block of a specified size is transferred per request. A designated number of block transfers are executed. Addresses are specified in MARA and MARB. The block area address can be either held fixed or cycled. Table 8.10 indicates the register functions in block transfer mode. Table 8.10 Register Functions in Block Transfer Mode Register Function Initial Setting Source address Operation Incremented or decremented once per transfer, or held fixed Incremented or decremented once per transfer, or held fixed Decremented once per transfer until H'00 is reached, then reloaded from ETCRAL Held fixed 23 MARA 23 MARB 7 0 Source address register Destination address register Block size counter 0 Destination address Block size 0 ETCRAH 7 0 Initial block size Block size ETCRAL 15 ETCRB 0 Block transfer counter Number of block transfers Decremented once per block transfer until H'0000 is reached and the transfer ends Legend MARA: MARB: ETCRA: ETCRB: Memory address register A Memory address register B Execute transfer count register A Execute transfer count register B The source and destination addresses are both 24-bit addresses. MARA specifies the source address. MARB specifies the destination address. MARA and MARB can be independently incremented, decremented, or held fixed as data is transferred. One of these registers operates as a block area register: even if it is incremented or decremented, it is restored to its initial value at the end of each block transfer. The TMS bit in DTCRB selects whether the block area is the source or destination. Rev. 2.0, 03/01, page 220 of 822 If M (1 to 255) is the size of the block transferred at each request and N (1 to 65,536) is the number of blocks to be transferred, then ETCRAH and ETCRAL should initially be set to M and ETCRB should initially be set to N. Figure 8.10 illustrates how block transfer mode operates. In this figure, bit TMS is cleared to 0, meaning the block area is the destination. TA Transfer Block 1 Block area BA Address T B Address B B Block 2 M bytes or words are transferred per request Block N Legend L A = initial setting of MARA L B = initial setting of MARB M = initial setting of ETCRAH and ETCRAL N = initial setting of ETCRB T A = LA B A = L A + SAIDE (-1) SAID (2 DTSZ M - 1) T B = LB B B = L B + DAIDE (-1) DAID (2 DTSZ M - 1) * * * * * * Figure 8.10 Operation in Block Transfer Mode Rev. 2.0, 03/01, page 221 of 822 When activated by a transfer request, the DMAC executes a burst transfer. During the transfer MARA and MARB are updated according to the DTCR settings, and ETCRAH is decremented. When ETCRAH reaches H'00, it is reloaded from ETCRAL to restore the initial value. The memory address register of the block area is also restored to its initial value, and ETCRB is decremented. If ETCRB is not H'0000, the DMAC then waits for the next transfer request. ETCRAH and ETCRAL should be initially set to the same value. The above operation is repeated until ETCRB reaches H'0000, at which point the DTE bit is cleared to 0 and the transfer ends. If the DTIE bit is set to 1, a CPU interrupt is requested at this time. Figure 8.11 shows examples of a block transfer with byte data size when the block area is the destination. In (a) the block area address is cycled. In (b) the block area address is held fixed. Transfers can be requested (activated) by compare match/input capture A interrupts from ITU channels 0 to 3, and by external request signals. For the detailed settings see section 8.3.4, Data Transfer Control Registers (DTCR). Rev. 2.0, 03/01, page 222 of 822 Start (DTE = DTME = 1) Start (DTE = DTME = 1) Transfer requested? Yes Get bus No Transfer requested? Yes Get bus No Read from MARA address MARA = MARA + 1 Write to MARB address MARB = MARB + 1 ETCRAH = ETCRAH - 1 No ETCRAH = H'00 Yes Release bus ETCRAH = ETCRAL MARB = MARB - ETCRAL ETCRB = ETCRB - 1 No Read from MARA address MARA = MARA + 1 Write to MARB address ETCRAH = ETCRAH - 1 No ETCRAH = H'00 Yes Release bus ETCRAH = ETCRAL ETCRB = ETCRB - 1 No ETCRB = H'0000 Yes Clear DTE to 0 and end transfer ETCRB = H'0000 Yes Clear DTE to 0 and end transfer a. DTSZ = TMS = 0 SAID = DAID = 0 SAIDE = DAIDE = 1 b. DTSZ = TMS = 0 SAID = 0 SAIDE = 1 DAIDE = 0 Figure 8.11 Block Transfer Mode Flowcharts (Examples) Rev. 2.0, 03/01, page 223 of 822 Figure 8.12 shows a sample setup procedure for block transfer mode. Block transfer mode 1. Set the source address in MARA. 2. Set the destination address in MARB. Set source address 1 3. Set the block transfer count in ETCRB. 4. Set the block size (number of bytes or words) in both ETCRAH and ETCRAL. 5. Set the DTCRB bits as follows. * Clear the DTME bit to 0. * Set the DAID and DAIDE bits to select whether MARB is incremented, decremented, or held fixed. * Set or clear the TMS bit to make the block area the source or destination. * Select the DMAC activation source with bits DTS2B to DTS0B. 6. Set the DTCRA bits as follows. * Clear the DTE to 0. * Select byte size or word size with the DTSZ bit. * Set the SAID and SAIDE bits to select whether MARA is incremented, decremented, or held fixed. * Set or clear the DTIE bit to enable or disable the CPU interrupt at the end of the transfer. * Set bits DTS2A to DTS0A all to 1 to select block transfer mode. 7. Read DTCRB with DTME cleared to 0. 8. Set the DTME bit to 1 in DTCRB. 9. Read DTCRA with DTE cleared to 0. Set destination address 2 Set block transfer count 3 Set block size 4 Set DTCRB (1) 5 Set DTCRA (1) 6 Read DTCRB 7 Set DTCRB (2) 8 Read DTCRA 9 10. Set the DTE bit to 1 in DTCRA to enable the transfer. Set DTCRA (2) 10 Block transfer mode Note: Carry out settings 1 to 10 with the DEND interrupt masked in the CPU. If an NMI interrupt occurs during the setup procedure, it may clear the DTME bit to 0, in which case the transfer will not start. Figure 8.12 Block Transfer Mode Setup Procedure (Example) Rev. 2.0, 03/01, page 224 of 822 8.4.7 DMAC Activation The DMAC can be activated by an internal interrupt, external request, or auto-request. The available activation sources differ depending on the transfer mode and channel as indicated in table 8.11. Table 8.11 DMAC Activation Sources Short Address Mode Activation Source Internal interrupts IMIA0 IMIA1 IMIA2 IMIA3 TXI0 RXI0 External requests Falling edge of '5(4 Low input at '5(4 Auto-request Channels 0A and 1A Yes Yes Yes Yes Yes Yes No No No Channels 0B and 1B Yes Yes Yes Yes Yes Yes Yes Yes No Full Address Mode Normal No No No No No No Yes Yes Yes Block Yes Yes Yes Yes No No Yes No No Activation by Internal Interrupts: When an interrupt request is selected as a DMAC activation source and the DTE bit is set to 1, that interrupt request is not sent to the CPU. It is not possible for an interrupt request to activate the DMAC and simultaneously generate a CPU interrupt. When the DMAC is activated by an interrupt request, the interrupt request flag is cleared automatically. If the same interrupt is selected to activate two or more channels, the interrupt request flag is cleared when the highest-priority channel is activated, but the transfer request is held pending on the other channels in the DMAC, which are activated in their priority order. Rev. 2.0, 03/01, page 225 of 822 Activation by External Request: If an external request ('5(4 pin) is selected as an activation source, the '5(4 pin becomes an input pin and the corresponding 7(1' pin becomes an output pin, regardless of the port data direction register (DDR) settings. The '5(4 input can be levelsensitive or edge-sensitive. In short address mode and normal mode, an external request operates as follows. If edge sensing is selected, one byte or word is transferred each time a high-to-low transition of the '5(4 input is detected. If the next edge is input before the transfer is completed, the next transfer may not be executed. If level sensing is selected, the transfer continues while '5(4 is low, until the transfer is completed. The bus is released temporarily after each byte or word has been transferred, however. If the '5(4 input goes high during a transfer, the transfer is suspended after the current byte or word has been transferred. When '5(4 goes low, the request is held internally until one byte or word has been transferred. The 7(1' signal goes low during the last write cycle. In block transfer mode, an external request operates as follows. Only edge-sensitive transfer requests are possible in block transfer mode. Each time a high-to-low transition of the '5(4 input is detected, a block of the specified size is transferred. The 7(1' signal goes low during the last write cycle in each block. Activation by Auto-Request: The transfer starts as soon as enabled by register setup, and continues until completed. Cycle-steal mode or burst mode can be selected. In cycle-steal mode the DMAC releases the bus temporarily after transferring each byte or word. Normally, DMAC cycles alternate with CPU cycles. In burst mode the DMAC keeps the bus until the transfer is completed, unless there is a higherpriority bus request. If there is a higher-priority bus request, the bus is released after the current byte or word has been transferred. Rev. 2.0, 03/01, page 226 of 822 8.4.8 DMAC Bus Cycle Figure 8.13 shows an example of the timing of the basic DMAC bus cycle. This example shows a word-size transfer from a 16-bit two-state access area to an 8-bit three-state access area. When the DMAC gets the bus from the CPU, after one dead cycle (Td), it reads from the source address and writes to the destination address. During these read and write operations the bus is not released even if there is another bus request. DMAC cycles comply with bus controller settings in the same way as CPU cycles. CPU cycle T1 T2 T1 T2 Td T1 DMAC cycle (word transfer) T2 T1 T2 T3 T1 T2 T3 T1 CPU cycle T2 T1 T2 Source address Address bus Destination address Figure 8.13 DMA Transfer Bus Timing (Example) Rev. 2.0, 03/01, page 227 of 822 Figure 8.14 shows the timing when the DMAC is activated by low input at a '5(4 pin. This example shows a word-size transfer from a 16-bit two-state access area to another 16-bit two-state access area. The DMAC continues the transfer while the '5(4 pin is held low. CPU cycle T1 T2 T3 Td DMAC cycle T1 T2 T1 T2 CPU cycle T1 T2 Td DMAC cycle (last transfer cycle) T1 T2 T1 T2 CPU cycle T1 T2 Source Destination address address Address bus Source Destination address address , Figure 8.14 Bus Timing of DMA Transfer Requested by Low '5(4 Input Rev. 2.0, 03/01, page 228 of 822 Figure 8.15 shows an auto-requested burst-mode transfer. This example shows a transfer of three words from a 16-bit two-state access area to another 16-bit two-state access area. CPU cycle T1 Source address Address bus Destination address T2 Td T1 T2 T1 T2 DMAC cycle T1 T2 T1 T2 T1 T2 T1 T2 CPU cycle T1 T2 , Figure 8.15 Burst DMA Bus Timing When the DMAC is activated from a '5(4 pin there is a minimum interval of four states from when the transfer is requested until the DMAC starts operating. The '5(4 pin is not sampled during the time between the transfer request and the start of the transfer. In short address mode and normal mode, the pin is next sampled at the end of the read cycle. In block transfer mode, the pin is next sampled at the end of one block transfer. Rev. 2.0, 03/01, page 229 of 822 Figure 8.16 shows the timing when the DMAC is activated by the falling edge of '5(4 in normal mode. CPU cycle T2 T1 T2 CPU cycle T2 T1 T2 T1 T2 Td DMAC cycle T1 T2 T1 DMAC cycle Td T1 T2 Address bus , Minimum 4 states Next sampling point Figure 8.16 Timing of DMAC Activation by Falling Edge of '5(4 in Normal Mode Rev. 2.0, 03/01, page 230 of 822 Figure 8.17 shows the timing when the DMAC is activated by level-sensitive low '5(4 input in normal mode. CPU cycle T2 T1 T2 T1 T2 Td DMAC cycle T1 T2 T1 T2 T1 CPU cycle T2 T1 T2 T1 Address bus , Minimum 4 states Next sampling point Figure 8.17 Timing of DMAC Activation by Low '5(4 Level in Normal Mode Rev. 2.0, 03/01, page 231 of 822 Figure 8.18 shows the timing when the DMAC is activated by the falling edge of '5(4 in block transfer mode. End of 1 block transfer DMAC cycle T1 T2 T1 T2 T1 T2 T1 T2 T1 CPU cycle T2 T1 T2 DMAC cycle Td T1 T2 Address bus , Next sampling Minimum 4 states Figure 8.18 Timing of DMAC Activation by Falling Edge of '5(4 in Block Transfer Mode Rev. 2.0, 03/01, page 232 of 822 8.4.9 DMAC Multiple-Channel Operation The DMAC channel priority order is: channel 0 > channel 1 and channel A > channel B. Table 8.12 shows the complete priority order. Table 8.12 Channel Priority Order Short Address Mode Channel 0A Channel 0B Channel 1A Channel 1B Channel 1 Full Address Mode Channel 0 Priority High Low If transfers are requested on two or more channels simultaneously, or if a transfer on one channel is requested during a transfer on another channel, the DMAC operates as follows. 1. When a transfer is requested, the DMAC requests the bus right. When it gets the bus right, it starts a transfer on the highest-priority channel at that time. 2. Once a transfer starts on one channel, requests to other channels are held pending until that channel releases the bus. 3. After each transfer in short address mode, and each externally-requested or cycle-steal transfer in normal mode, the DMAC releases the bus and returns to step 1. After releasing the bus, if there is a transfer request for another channel, the DMAC requests the bus again. 4. After completion of a burst-mode transfer, or after transfer of one block in block transfer mode, the DMAC releases the bus and returns to step 1. If there is a transfer request for a higher-priority channel or a bus request from a higher-priority bus master, however, the DMAC releases the bus after completing the transfer of the current byte or word. After releasing the bus, if there is a transfer request for another channel, the DMAC requests the bus again. Figure 8.19 shows the timing when channel 0A is set up for I/O mode and channel 1 for burst mode, and a transfer request for channel 0A is received while channel 1 is active. Rev. 2.0, 03/01, page 233 of 822 DMAC cycle (channel 1) T1 Address bus T2 T1 CPU cycle T2 Td DMAC cycle (channel 0A) T1 T2 T1 T2 T1 CPU cycle T2 Td DMAC cycle (channel 1) T1 T2 T1 T2 , Figure 8.19 Timing of Multiple-Channel Operations 8.4.10 External Bus Requests, Refresh Controller, and DMAC During a DMA transfer, if the bus right is requested by an external bus request signal (%5(4) or by the refresh controller, the DMAC releases the bus after completing the transfer of the current byte or word. If there is a transfer request at this point, the DMAC requests the bus right again. Figure 8.20 shows an example of the timing of insertion of a refresh cycle during a burst transfer on channel 0. DMAC cycle (channel 0) T1 Address bus T2 T1 T2 T1 T2 T1 T2 Refresh cycle T1 T2 Td DMAC cycle (channel 0) T1 T2 T1 T2 T1 T2 , Figure 8.20 Bus Timing of Refresh Controller and DMAC Rev. 2.0, 03/01, page 234 of 822 8.4.11 NMI Interrupts and DMAC NMI interrupts do not affect DMAC operations in short address mode. If an NMI interrupt occurs during a transfer in full address mode, the DMAC suspends operations. In full address mode, a channel is enabled when its DTE and DTME bits are both set to 1. NMI input clears the DTME bit to 0. After transferring the current byte or word, the DMAC releases the bus to the CPU. In normal mode, the suspended transfer resumes when the CPU sets the DTME bit to 1 again. Check that the DTE bit is set to 1 and the DTME bit is cleared to 0 before setting the DTME bit to 1. Figure 8.21 shows the procedure for resuming a DMA transfer in normal mode on channel 0 after the transfer was halted by NMI input. Resuming DMA transfer in normal mode 1. Check that DTE = 1 and DTME = 0. 2. Read DTCRB while DTME = 0, then write 1 in the DTME bit. 1 No DTE = 1 DTME = 0 Yes Set DTME to 1 2 DMA transfer continues End Figure 8.21 Procedure for Resuming a DMA Transfer Halted by NMI (Example) For information about NMI interrupts in block transfer mode, see section 8.6.6, NMI Interrupts and Block Transfer Mode. Rev. 2.0, 03/01, page 235 of 822 8.4.12 Aborting a DMA Transfer When the DTE bit in an active channel is cleared to 0, the DMAC halts after transferring the current byte or word. The DMAC starts again when the DTE bit is set to 1. In full address mode, the DTME bit can be used for the same purpose. Figure 8.22 shows the procedure for aborting a DMA transfer by software. DMA transfer abort 1. Clear the DTE bit to 0 in DTCR. To avoid generating an interrupt when aborting a DMA transfer, clear the DTIE bit to 0 simultaneously. 1 Set DTCR DMA transfer aborted Figure 8.22 Procedure for Aborting a DMA Transfer Rev. 2.0, 03/01, page 236 of 822 8.4.13 Exiting Full Address Mode Figure 8.23 shows the procedure for exiting full address mode and initializing the pair of channels. To set the channels up in another mode after exiting full address mode, follow the setup procedure for the relevant mode. Exiting full address mode 1. Clear the DTE bit to 0 in DTCRA, or wait for the transfer to end and the DTE bit to be cleared to 0. 2. Clear all DTCRB bits to 0. 1 Halt the channel 3. Clear all DTCRA bits to 0. Initialize DTCRB 2 Initialize DTCRA 3 Initialized and halted Figure 8.23 Procedure for Exiting Full Address Mode (Example) Rev. 2.0, 03/01, page 237 of 822 8.4.14 DMAC States in Reset State, Standby Modes, and Sleep Mode When the chip is reset or enters hardware or software standby mode, the DMAC is initialized and halts. DMAC operations continue in sleep mode. Figure 8.24 shows the timing of a cycle-steal transfer in sleep mode. Sleep mode CPU cycle T2 Td DMAC cycle T1 T2 T1 T2 Td DMAC cycle T1 T2 T1 T2 Td Address bus , Figure 8.24 Timing of Cycle-Steal Transfer in Sleep Mode Rev. 2.0, 03/01, page 238 of 822 8.5 Interrupts The DMAC generates only DMA-end interrupts. Table 8.13 lists the interrupts and their priority. Table 8.13 DMAC Interrupts Description Interrupt DEND0A DEND0B DEND1A DEND1B Short Address Mode End of transfer on channel 0A End of transfer on channel 0B End of transfer on channel 1A End of transfer on channel 1B Full Address Mode End of transfer on channel 0 -- End of transfer on channel 1 -- Interrupt Priority High Low Each interrupt is enabled or disabled by the DTIE bit in the corresponding data transfer control register (DTCR). Separate interrupt signals are sent to the interrupt controller. The interrupt priority order among channels is channel 0 > channel 1 and channel A > channel B. Figure 8.25 shows the DMA-end interrupt logic. An interrupt is requested whenever DTE = 0 and DTIE = 1. DTE DMA-end interrupt DTIE Figure 8.25 DMA-End Interrupt Logic The DMA-end interrupt for the B channels (DENDB) is unavailable in full address mode. The DTME bit does not affect interrupt operations. Rev. 2.0, 03/01, page 239 of 822 8.6 8.6.1 Usage Notes Note on Word Data Transfer Word data cannot be accessed starting at an odd address. When word-size transfer is selected, set even values in the memory and I/O address registers (MAR and IOAR). 8.6.2 DMAC Self-Access The DMAC itself cannot be accessed during a DMAC cycle. DMAC registers cannot be specified as source or destination addresses. 8.6.3 Longword Access to Memory Address Registers A memory address register can be accessed as longword data at the MARR address. Example MOV.L MOV.L #LBL, ER0 ER0, @MARR Four byte accesses are performed. Note that the CPU may release the bus between the second byte (MARE) and third byte (MARH). Memory address registers should be written and read only when the DMAC is halted. 8.6.4 Note on Full Address Mode Setup Full address mode is controlled by two registers: DTCRA and DTCRB. Care must be taken to prevent the B channel from operating in short address mode during the register setup. The enable bits (DTE and DTME) should not be set to 1 until the end of the setup procedure. 8.6.5 Note on Activating DMAC by Internal Interrupts When using an internal interrupt to activate the DMAC, make sure that the interrupt selected as the activating source does not occur during the interval after it has been selected but before the DMAC has been enabled. The on-chip supporting module that will generate the interrupt should not be activated until the DMAC has been enabled. If the DMAC must be enabled while the onchip supporting module is active, follow the procedure in figure 8.26. Rev. 2.0, 03/01, page 240 of 822 Enabling of DMAC 1. While the DTE bit is cleared to 0, interrupt requests are sent to the CPU. 1 2. Clear the interrupt enable bit to 0 in the interrupt-generating on-chip supporting module. 3. Enable the DMAC. Yes Interrupt handling by CPU Selected interrupt requested? No 4. Enable the DMAC-activating interrupt. 2 Clear selected interrupt's enable bit to 0 Enable DMAC 3 Set selected interrupt's enable bit to 1 4 DMAC operates Figure 8.26 Procedure for Enabling DMAC while On-Chip Supporting Module is Operating (Example) If the DTE bit is set to 1 but the DTME bit is cleared to 0, the DMAC is halted and the selected activating source cannot generate a CPU interrupt. If the DMAC is halted by an NMI interrupt, for example, the selected activating source cannot generate CPU interrupts. To terminate DMAC operations in this state, clear the DTE bit to 0 to allow CPU interrupts to be requested. To continue DMAC operations, carry out steps 2 and 4 in figure 8.26 before and after setting the DTME bit to 1. When an ITU interrupt activates the DMAC, make sure the next interrupt does not occur before the DMA transfer ends. If one ITU interrupt activates two or more channels, make sure the next interrupt does not occur before the DMA transfers end on all the activated channels. If the next interrupt occurs before a transfer ends, the channel or channels for which that interrupt was selected may fail to accept further activation requests. Rev. 2.0, 03/01, page 241 of 822 8.6.6 NMI Interrupts and Block Transfer Mode If an NMI interrupt occurs in block transfer mode, the DMAC operates as follows. * When the NMI interrupt occurs, the DMAC finishes transferring the current byte or word, then clears the DTME bit to 0 and halts. The halt may occur in the middle of a block. It is possible to find whether a transfer was halted in the middle of a block by checking the block size counter. If the block size counter does not have its initial value, the transfer was halted in the middle of a block. * If the transfer is halted in the middle of a block, the activating interrupt flag is cleared to 0. The activation request is not held pending. * While the DTE bit is set to 1 and the DTME bit is cleared to 0, the DMAC is halted and does not accept activating interrupt requests. If an activating interrupt occurs in this state, the DMAC does not operate and does not hold the transfer request pending internally. Neither is a CPU interrupt requested. For this reason, before setting the DTME bit to 1, first clear the enable bit of the activating interrupt to 0. Then, after setting the DTME bit to 1, set the interrupt enable bit to 1 again. See section 8.6.5, Note on Activating DMAC by Internal Interrupts. * When the DTME bit is set to 1, the DMAC waits for the next transfer request. If it was halted in the middle of a block transfer, the rest of the block is transferred when the next transfer request occurs. Otherwise, the next block is transferred when the next transfer request occurs. 8.6.7 Memory and I/O Address Register Values Table 8.14 indicates the address ranges that can be specified in the memory and I/O address registers (MAR and IOAR). Table 8.14 Address Ranges Specifiable in MAR and IOAR 1-Mbyte Mode MAR IOAR H'00000 to H'FFFFF (0 to 1048575) H'FFF00 to H'FFFFF (1048320 to 1048575) 16-Mbyte Mode H'000000 to H'FFFFFF (0 to 16777215) H'FFFF00 to H'FFFFFF (16776960 to 16777215) MAR bits 23 to 20 are ignored in 1-Mbyte mode. Rev. 2.0, 03/01, page 242 of 822 8.6.8 Bus Cycle when Transfer is Aborted When a transfer is aborted by clearing the DTE bit or suspended by an NMI that clears the DTME bit, if this halts a channel for which the DMAC has a transfer request pending internally, a dead cycle may occur. This dead cycle does not update the halted channel's address register or counter value. Figure 8.27 shows an example in which an auto-requested transfer in cycle-steal mode on channel 0 is aborted by clearing the DTE bit in channel 0. CPU cycle T1 T2 Td DMAC cycle T1 T2 T1 T2 T1 CPU cycle T2 T3 Td DMAC cycle Td CPU cycle T1 T2 Address bus , DTE bit is cleared Figure 8.27 Bus Timing at Abort of DMA Transfer in Cycle-Steal Mode Rev. 2.0, 03/01, page 243 of 822 Rev. 2.0, 03/01, page 244 of 822 Section 9 I/O Ports 9.1 Overview The H8/3052F has 10 input/output ports (ports 1, 2, 3, 4, 5, 6, 8, 9, A, and B) and one input port (port 7). Table 9.1 summarizes the port functions. The pins in each port are multiplexed as shown in table 9.1. Each port has a data direction register (DDR) for selecting input or output, and a data register (DR) for storing output data. In addition to these registers, ports 2, 4, and 5 have an input pull-up MOS control register (PCR) for switching input pull-up MOS transistors on and off. Ports 1 to 6 and port 8 can drive one TTL load and a 90-pF capacitive load. Ports 9, A, and B can drive one TTL load and a 30-pF capacitive load. Ports 1 to 6 and 8 to B can drive a darlington pair. Ports 1, 2, 5, and B can drive LEDs (with 10-mA current sink). Pins P82 to P80, PA7 to PA0, and PB3 to PB0 have Schmitt-trigger input circuits. For block diagrams of the ports see appendix C, I/O Port Block Diagrams. Rev. 2.0, 03/01, page 245 of 822 Table 9.1 Port Port Functions Pins Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Description Port 1 * 8-bit I/O port P17 to P10/ A7 to A0 * Can drive LEDs Address output pins (A7 to A0) Address output (A7 Generic to A0) and generic input/ output input DDR = 0: generic input DDR = 1: address output Port 2 * 8-bit I/O port P27 to P20/ * Input pull-up A15 to A8 MOS * Can drive LEDs Address output pins (A15 to A8) Address output (A15 Generic to A8) and generic input/ input output DDR = 0: generic input DDR = 1: address output Port 3 * 8-bit I/O port P37 to P30/ D15 to D8 Port 4 * 8-bit I/O port P47 to P40/ * Input pull-up D7 to D0 MOS Port 5 * 4-bit I/O port P53 to P50/ * Input pull-up A19 to A16 MOS * Can drive LEDs Data input/output (D15 to D8) Generic input/ output Generic input/ output Data input/output (D7 to D0) and 8-bit generic input/output 8-bit bus mode: generic input/output 16-bit bus mode: data input/output Address output (A19 to A16) Address output (A19 Generic to A16) and 4-bit input/ generic input output DDR = 0: generic input DDR = 1: address output Port 6 * 7-bit I/O port P66//:5, P65/+:5, P64/5', P63/$6 P62/%$&., P61/%5(4, P60/:$,7 Port 7 * 8-bit I/O port P77/AN7/DA1, P76/AN6/DA0 P75 to P70/ AN5 to AN0 Bus control signal output (/:5, +:5, 5', $6) Generic input/ output Bus control signal input/output (%$&., %5(4, :$,7) and 3bit generic input/output Analog input (AN7, AN6) to A/D converter, analog output (DA1, DA0) from D/A converter, and generic input Analog input (AN5 to AN0) to A/D converter, and generic input Rev. 2.0, 03/01, page 246 of 822 Port Description Pins Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Generic input/ output IRQ3 to IRQ0 input and generic input/ output Port 8 * 5-bit I/O port P84/&60 * P82 to P80 have Schmitt inputs P83/&61/,543, P82/&S2/,542, P81/&63/,541 DDR = 0: generic input DDR = 1 (reset value): &60 output ,543 to ,541 input, &61 to &63 output, and generic input DDR = 0 (reset value): generic input DDR = 1: &61 to &63 output P80/5)6+/,540 ,540 input, 5)6+ output, and generic input/output Port 9 * 6-bit I/O port P95/SCK1/,545, Input and output (SCK1, SCK0, RxD1, RxD0, TxD1, TxD0) for serial P94/SCK0/,544, communication interfaces 1 and 0 (SCI1/0), ,545 and ,544 input, and 6P93/RxD1, bit generic input/output P92/RxD0, P91/TxD1, P90/TxD0 Port A * 8-bit I/O port PA7/TP7/ TIOCB2/A20 * Schmitt inputs output Output (TP7) from Address output (A20) programmable timing pattern controller (TPC), input or output (TIOCB2) for 16-bit integrated timer unit (ITU), and generic input/output TPC output (TP6 to TP4), ITU input and output (TIOCA2, TIOCB1, TIOCA1), &64 to &66 output, and generic input/ output TPC output (TP6 to TP4), ITU input and output (TIOCA2, TIOCB1, TIOCA1), address output (A23 to A21), &64 to &66 output, and generic input/output Address TPC TPC output output output (A20) (TP7), (TP7), ITU input ITU input or output or output (TIOCB2), (TIOCB2), and and generic generic input/ input/ output output TPC output (TP6 to TP4), ITU input and output (TIOCA2, TIOCB1, TIOCA1), address output (A13 to A11), &64 to &66 output, and generic input/ output TPC output (TP6 to TP4), ITU input and output (TIOCA2, TIOCB1, TIOCA1), address output (A13 to A11), &64 to &66 output, and generic input/out put TPC output (TP6 to TP4), ITU input and output (TIOCA2, TIOCB1, TIOCA1), and generic input/ output PA6/TP6/ TIOCA2/A21/&64 PA5/TP5/ TIOCB1/A22/&65 PA4/TP4/ TIOCA1/A23/&66 Rev. 2.0, 03/01, page 247 of 822 Port Description Pins Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Port A * 8-bit I/O port PA3/TP3/ TPC output (TP3 to TP0), output (7(1'1, 7(1'0) from DMA controller TIOCB0/ (DMAC), ITU input and output (TCLKD, TCLKC, TCLKB, TCLKA, * Schmitt TIOCB0, TIOCA0), and generic input/output inputs output TCLKD, PA2/TP2/ TIOCA0/ TCLKC, PA1/TP1/ 7(1'1/TCLKB, PA0/TP0/ 7(1'0/TCLKA Port B * 8-bit I/O port PB7/TP15/ TPC output (TP15), DMAC input ('5(41), trigger input ($'75*) to A/D '5(41/$'75* converter, and generic input/output * Can drive LEDs TPC PB6/TP14/ TPC output (TP14), DMAC input ('5(40), &67 output, and '5(40,/&67 output generic input/output * PB3 to PB0 (TP14), have Schmitt DMAC inputs input ('5(40), and generic input/ output PB5/TP13/ TOCXB4, PB4/TP12/ TOCXA4, PB3/TP11/ TIOCB4, PB2/TP10/ TIOCA4, PB1/TP9/ TIOCB3, PB0/TP8/ TIOCA3 TPC output (TP13 to TP8), ITU input and output (TOCXB4, TOCXA4, TIOCB4, TIOCA4, TIOCB3, TIOCA3), and generic input/output Rev. 2.0, 03/01, page 248 of 822 9.2 9.2.1 Port 1 Overview Port 1 is an 8-bit input/output port with the pin configuration shown in figure 9.1. The pin functions differ between the expanded modes with on-chip ROM disabled, expanded modes with on-chip ROM enabled, and single-chip mode. In modes 1 to 4 (expanded modes with on-chip ROM disabled), they are address bus output pins (A7 to A0). In modes 5 and 6 (expanded modes with on-chip ROM enabled), settings in the port 1 data direction register (P1DDR) can designate pins for address bus output (A7 to A0) or generic input. In mode 7 (single-chip mode), port 1 is a generic input/output port. When DRAM is connected to area 3, A7 to A0 output row and column addresses in read and write cycles. For details see section 7, Refresh Controller. Pins in port 1 can drive one TTL load and a 90-pF capacitive load. They can also drive a darlington transistor pair. Port 1 pins P17 /A 7 P16 /A 6 P15 /A 5 Port 1 P14 /A 4 P13 /A 3 P12 /A 2 P11 /A 1 P10 /A 0 Modes 1 to 4 A 7 (output) A 6 (output) A 5 (output) A 4 (output) A 3 (output) A 2 (output) A 1 (output) A 0 (output) Modes 5 and 6 P17 (input)/A 7 (output) P16 (input)/A 6 (output) P15 (input)/A 5 (output) P14 (input)/A 4 (output) P13 (input)/A 3 (output) P12 (input)/A 2 (output) P11 (input)/A 1 (output) P10 (input)/A 0 (output) Mode 7 P17 (input/output) P16 (input/output) P15 (input/output) P14 (input/output) P13 (input/output) P12 (input/output) P11 (input/output) P10 (input/output) Figure 9.1 Port 1 Pin Configuration Rev. 2.0, 03/01, page 249 of 822 9.2.2 Register Configuration Table 9.2 summarizes the registers of port 1. Table 9.2 Port 1 Registers Initial Value Address* H'FFC0 H'FFC2 Name Port 1 data direction register Port 1 data register Abbreviation P1DDR P1DR R/W W R/W Modes 1 to 4 H'FF H'00 Modes 5 to 7 H'00 H'00 Note: * Lower 16 bits of the address. Port 1 Data Direction Register (P1DDR) P1DDR is an 8-bit write-only register that can select input or output for each pin in port 1. Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 1 -- 0 W 6 1 -- 0 W 5 1 -- 0 W 4 1 -- 0 W 3 1 -- 0 W 2 1 -- 0 W 1 1 -- 0 W 0 1 -- 0 W P1 7 DDR P1 6 DDR P1 5 DDR P1 4 DDR P1 3 DDR P1 2 DDR P1 1 DDR P1 0 DDR Port 1 data direction 7 to 0 These bits select input or output for port 1 pins * Modes 1 to 4 (Expanded Modes with On-Chip ROM Disabled) P1DDR values are fixed at 1 and cannot be modified. Port 1 functions as an address bus. * Modes 5 and 6 (Expanded Modes with On-Chip ROM Enabled) A pin in port 1 becomes an address output pin if the corresponding P1DDR bit is set to 1, and a generic input pin if this bit is cleared to 0. * Mode 7 (Single-Chip Mode) Port 1 functions as an input/output port. A pin in port 1 becomes an output pin if the corresponding P1DDR bit is set to 1, and an input pin if this bit is cleared to 0. In modes 5 to 7, P1DDR is a write-only register. Its value cannot be read. All bits return 1 when read. Rev. 2.0, 03/01, page 250 of 822 P1DDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a P1DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 1 Data Register (P1DR) P1DR is an 8-bit readable/writable register that stores port 1 output data. When this register is read, the pin logic level of a pin is read for bits for which the P1DDR setting is 0, and the P1DR value is read for bits for which the P1DDR setting is 1. Bit Initial value Read/Write 7 P17 0 R/W 6 P16 0 R/W 5 P15 0 R/W 4 P14 0 R/W 3 P13 0 R/W 2 P12 0 R/W 1 P11 0 R/W 0 P10 0 R/W Port 1 data 7 to 0 These bits store data for port 1 pins P1DR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 251 of 822 9.3 9.3.1 Port 2 Overview Port 2 is an 8-bit input/output port with the pin configuration shown in figure 9.2. The pin functions differ according to the operating mode. In modes 1 to 4 (expanded modes with on-chip ROM disabled), port 2 consists of address bus output pins (A15 to A8). In modes 5 and 6 (expanded modes with on-chip ROM enabled), settings in the port 2 data direction register (P2DDR) can designate pins for address bus output (A15 to A8) or generic input. In mode 7 (single-chip mode), port 2 is a generic input/output port. When DRAM is connected to area 3, A9 and A8 output row and column addresses in read and write cycles. For details see section 7, Refresh Controller. Port 2 has software-programmable built-in pull-up MOS. Pins in port 2 can drive one TTL load and a 90-pF capacitive load. They can also drive a darlington transistor pair. Port 2 pins P27 /A 15 P26 /A 14 P25 /A 13 Port 2 P24 /A 12 P23 /A 11 P22 /A 10 P21 /A 9 P20 /A 8 Modes 1 to 4 A15 (output) A14 (output) A13 (output) A12 (output) A11 (output) A10 (output) A9 (output) A8 (output) Modes 5 and 6 P27 (input)/A15 (output) P26 (input)/A14 (output) P25 (input)/A13 (output) P24 (input)/A12 (output) P23 (input)/A11 (output) P22 (input)/A10 (output) P21 (input)/A9 (output) P20 (input)/A8 (output) Mode 7 P27 (input/output) P26 (input/output) P25 (input/output) P24 (input/output) P23 (input/output) P22 (input/output) P21 (input/output) P20 (input/output) Figure 9.2 Port 2 Pin Configuration Rev. 2.0, 03/01, page 252 of 822 9.3.2 Register Configuration Table 9.3 summarizes the registers of port 2. Table 9.3 Port 2 Registers Initial Value Address* H'FFC1 H'FFC3 H'FFD8 Name Port 2 data direction register Port 2 data register Port 2 input pull-up MOS control register Abbreviation P2DDR P2DR P2PCR R/W W R/W R/W Modes 1 to 4 H'FF H'00 H'00 Modes 5 to 7 H'00 H'00 H'00 Note: * Lower 16 bits of the address. Port 2 Data Direction Register (P2DDR) P2DDR is an 8-bit write-only register that can select input or output for each pin in port 2. Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 1 -- 0 W 6 1 -- 0 W 5 1 -- 0 W 4 1 -- 0 W 3 1 -- 0 W 2 1 -- 0 W 1 1 -- 0 W 0 1 -- 0 W P2 7 DDR P2 6 DDR P2 5 DDR P2 4 DDR P2 3 DDR P2 2 DDR P2 1 DDR P2 0 DDR Port 2 data direction 7 to 0 These bits select input or output for port 2 pins * Modes 1 to 4 (Expanded Modes with On-Chip ROM Disabled) P2DDR values are fixed at 1 and cannot be modified. Port 2 functions as an address bus. * Modes 5 and 6 (Expanded Modes with On-Chip ROM Enabled) Following a reset, port 2 is an input port. A pin in port 2 becomes an address output pin if the corresponding P2DDR bit is set to 1, and a generic input port if this bit is cleared to 0. * Mode 7 (Single-Chip Mode) Port 2 functions as an input/output port. A pin in port 2 becomes an output port if the corresponding P2DDR bit is set to 1, and an input port if this bit is cleared to 0. In modes 5 to 7, P2DDR is a write-only register. Its value cannot be read. All bits return 1 when read. Rev. 2.0, 03/01, page 253 of 822 P2DDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a P2DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 2 Data Register (P2DR) P2DR is an 8-bit readable/writable register that stores output data for pins P27 to P20. When a bit in P2DDR is set to 1, if port 2 is read the value of the corresponding P2DR bit is returned. When a bit in P2DDR is cleared to 0, if port 2 is read the corresponding pin level is read. Bit Initial value Read/Write 7 P2 7 0 R/W 6 P2 6 0 R/W 5 P2 5 0 R/W 4 P2 4 0 R/W 3 P2 3 0 R/W 2 P2 2 0 R/W 1 P2 1 0 R/W 0 P2 0 0 R/W Port 2 data 7 to 0 These bits store data for port 2 pins P2DR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Port 2 Input Pull-Up MOS Control Register (P2PCR) P2PCR is an 8-bit readable/writable register that controls the MOS input pull-up transistors in port 2. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W P2 7 PCR P2 6 PCR P2 5 PCR P2 4 PCR P2 3 PCR P2 2 PCR P2 1 PCR P2 0 PCR Port 2 input pull-up MOS control 7 to 0 These bits control input pull-up transistors built into port 2 In modes 5 to 7, when a P2DDR bit is cleared to 0 (selecting generic input), if the corresponding bit from P27PCR to P20PCR is set to 1, the input pull-up MOS is turned on. P2PCR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 254 of 822 Table 9.4 summarizes the states of the input pull-up transistors. Table 9.4 Mode 1 2 3 4 5 6 7 Legend Off: The input pull-up MOS is always off. On/off: The input pull-up MOS is on if P2PCR = 1 and P2DDR = 0. Otherwise, it is off. Off Off On/off On/off Input Pull-Up MOS States (Port 2) Reset Off Hardware Standby Mode Off Software Standby Mode Off Other Modes Off Rev. 2.0, 03/01, page 255 of 822 9.4 9.4.1 Port 3 Overview Port 3 is an 8-bit input/output port with the pin configuration shown in figure 9.3. Port 3 is a data bus in modes 1 to 6 (expanded modes) and a generic input/output port in mode 7 (single-chip mode). Pins in port 3 can drive one TTL load and a 90-pF capacitive load. They can also drive a darlington transistor pair. Port 3 pins P37 /D15 P36 /D14 P35 /D13 Port 3 P34 /D12 P33 /D11 P32 /D10 P31 /D9 P30 /D8 Modes 1 to 6 D15 (input/output) D14 (input/output) D13 (input/output) D12 (input/output) D11 (input/output) D10 (input/output) D9 (input/output) D8 (input/output) Mode 7 P37 (input/output) P36 (input/output) P35 (input/output) P34 (input/output) P33 (input/output) P32 (input/output) P31 (input/output) P30 (input/output) Figure 9.3 Port 3 Pin Configuration 9.4.2 Register Configuration Table 9.5 summarizes the registers of port 3. Table 9.5 Address* H'FFC4 H'FFC6 Port 3 Registers Name Port 3 data direction register Port 3 data register Abbreviation P3DDR P3DR R/W W R/W Initial Value H'00 H'00 Note: * Lower 16 bits of the address. Rev. 2.0, 03/01, page 256 of 822 Port 3 Data Direction Register (P3DDR) P3DDR is an 8-bit write-only register that can select input or output for each pin in port 3. Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W P3 7 DDR P3 6 DDR P3 5 DDR P3 4 DDR P3 3 DDR P3 2 DDR P3 1 DDR P3 0 DDR Port 3 data direction 7 to 0 These bits select input or output for port 3 pins * Modes 1 to 6 (Expanded Modes) Port 3 functions as a data bus. P3DDR is ignored. * Mode 7 (Single-Chip Mode) Port 3 functions as an input/output port. A pin in port 3 becomes an output port if the corresponding P3DDR bit is set to 1, and an input port if this bit is cleared to 0. P3DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P3DDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a P3DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 3 Data Register (P3DR) P3DR is an 8-bit readable/writable register that stores output data for pins P37 to P30. When a bit in P3DDR is set to 1, if port 3 is read the value of the corresponding P3DR bit is returned. When a bit in P3DDR is cleared to 0, if port 3 is read the corresponding pin level is read. Bit Initial value Read/Write 7 P3 7 0 R/W 6 P3 6 0 R/W 5 P3 5 0 R/W 4 P3 4 0 R/W 3 P3 3 0 R/W 2 P3 2 0 R/W 1 P3 1 0 R/W 0 P3 0 0 R/W Port 3 data 7 to 0 These bits store data for port 3 pins P3DR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 257 of 822 9.5 9.5.1 Port 4 Overview Port 4 is an 8-bit input/output port with the pin configuration shown in figure 9.4. The pin functions differ according to the operating mode. In modes 1 to 6 (expanded modes), when the bus width control register (ABWCR) designates areas 0 to 7 all as 8-bit-access areas, the chip operates in 8-bit bus mode and port 4 is a generic input/output port. When at least one of areas 0 to 7 is designated as a 16-bit-access area, the chip operates in 16-bit bus mode and port 4 becomes part of the data bus. In mode 7 (single-chip mode), port 4 is a generic input/output port. Port 4 has software-programmable built-in pull-up MOS. Pins in port 4 can drive one TTL load and a 90-pF capacitive load. They can also drive a darlington transistor pair. Port 4 pins P47 /D7 P46 /D6 P45 /D5 Port 4 P44 /D4 P43 /D3 P42 /D2 P41 /D1 P40 /D0 Modes 1 to 6 P47 (input/output)/D7 (input/output) P46 (input/output)/D6 (input/output) P45 (input/output)/D5 (input/output) P44 (input/output)/D4 (input/output) P43 (input/output)/D3 (input/output) P42 (input/output)/D2 (input/output) P41 (input/output)/D1 (input/output) P40 (input/output)/D0 (input/output) Mode 7 P47 (input/output) P46 (input/output) P45 (input/output) P44 (input/output) P43 (input/output) P42 (input/output) P41 (input/output) P40 (input/output) Figure 9.4 Port 4 Pin Configuration Rev. 2.0, 03/01, page 258 of 822 9.5.2 Register Configuration Table 9.6 summarizes the registers of port 4. Table 9.6 Address* H'FFC5 H'FFC7 H'FFDA Port 4 Registers Name Port 4 data direction register Port 4 data register Port 4 input pull-up MOS control register Abbreviation P4DDR P4DR P4PCR R/W W R/W R/W Initial Value H'00 H'00 H'00 Note: * Lower 16 bits of the address. Port 4 Data Direction Register (P4DDR) P4DDR is an 8-bit write-only register that can select input or output for each pin in port 4. Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W P4 7 DDR P4 6 DDR P4 5 DDR P4 4 DDR P4 3 DDR P4 2 DDR P4 1 DDR P4 0 DDR Port 4 data direction 7 to 0 These bits select input or output for port 4 pins * Modes 1 to 6 (Expanded Modes) When all areas are designated as 8-bit-access areas, selecting 8-bit bus mode, port 4 functions as a generic input/output port. A pin in port 4 becomes an output port if the corresponding P4DDR bit is set to 1, and an input port if this bit is cleared to 0. When at least one area is designated as a 16-bit-access area, selecting 16-bit bus mode, port 4 functions as part of the data bus. * Mode 7 (Single-Chip Mode) Port 4 functions as an input/output port. A pin in port 4 becomes an output port if the corresponding P4DDR bit is set to 1, and an input port if this bit is cleared to 0. P4DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P4DDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 259 of 822 ABWCR and P4DDR are not initialized in software standby mode. When port 4 functions as a generic input/output port, if a P4DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 4 Data Register (P4DR) P4DR is an 8-bit readable/writable register that stores output data for pins P47 to P40. When a bit in P4DDR is set to 1, if port 4 is read the value of the corresponding P4DR bit is returned. When a bit in P4DDR is cleared to 0, if port 4 is read the corresponding pin level is read. Bit Initial value Read/Write 7 P4 7 0 R/W 6 P4 6 0 R/W 5 P4 5 0 R/W 4 P4 4 0 R/W 3 P4 3 0 R/W 2 P4 2 0 R/W 1 P4 1 0 R/W 0 P4 0 0 R/W Port 4 data 7 to 0 These bits store data for port 4 pins P4DR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Port 4 Input Pull-Up MOS Control Register (P4PCR) P4PCR is an 8-bit readable/writable register that controls the MOS input pull-up transistors in port 4. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W P4 7 PCR P4 6 PCR P4 5 PCR P4 4 PCR P4 3 PCR P4 2 PCR P4 1 PCR P4 0 PCR Port 4 input pull-up MOS control 7 to 0 These bits control input pull-up MOS transistors built into port 4 In mode 7 (single-chip mode), and in 8-bit bus mode in modes 1 to 6 (expanded modes), when a P4DDR bit is cleared to 0 (selecting generic input), if the corresponding P4PCR bit is set to 1, the input pull-up MOS transistor is turned on. P4PCR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 260 of 822 Table 9.7 summarizes the states of the input pull-ups MOS in the 8-bit and 16-bit bus modes. Table 9.7 Mode 1 to 6 7 8-bit bus mode 16-bit bus mode Input Pull-Up MOS Transistor States (Port 4) Reset Off Hardware Standby Mode Off Software Standby Mode On/off Off On/off Other Modes On/off Off On/off Legend Off: The input pull-up MOS transistor is always off. On/off: The input pull-up MOS transistor is on if P4PCR = 1 and P4DDR = 0. Otherwise, it is off. Rev. 2.0, 03/01, page 261 of 822 9.6 9.6.1 Port 5 Overview Port 5 is a 4-bit input/output port with the pin configuration shown in figure 9.5. The pin functions differ depending on the operating mode. In modes 1 to 4 (expanded modes with on-chip ROM disabled), port 5 consists of address output pins (A19 to A16). In modes 5 and 6 (expanded modes with on-chip ROM enabled), settings in the port 5 data direction register (P5DDR) designate pins for address bus output (A19 to A16) or generic input. In mode 7 (single-chip mode), port 5 is a generic input/output port. Port 5 has software-programmable built-in pull-up MOS transistors. Pins in port 5 can drive one TTL load and a 90-pF capacitive load. They can also drive an LED or a darlington transistor pair. Port 5 pins P53 /A 19 Port 5 P52 /A 18 P51 /A 17 P50 /A 16 Modes 1 to 4 A19 (output) A18 (output) A17 (output) A16 (output) Modes 5 and 6 P5 3 (input)/A19 (output) P5 2 (input)/A18 (output) P5 1 (input)/A17 (output) P5 0 (input)/A16 (output) Mode 7 P5 3 (input/output) P5 2 (input/output) P5 1 (input/output) P5 0 (input/output) Figure 9.5 Port 5 Pin Configuration Rev. 2.0, 03/01, page 262 of 822 9.6.2 Register Configuration Table 9.8 summarizes the registers of port 5. Table 9.8 Port 5 Registers Initial Value Address* H'FFC8 H'FFCA H'FFDB Name Port 5 data direction register Port 5 data register Port 5 input pull-up MOS control register Abbreviation P5DDR P5DR P5PCR R/W W R/W R/W Modes 1 to 4 H'FF H'F0 H'F0 Modes 5 to 7 H'F0 H'F0 H'F0 Note: * Lower 16 bits of the address. Port 5 Data Direction Register (P5DDR) P5DDR is an 8-bit write-only register that can select input or output for each pin in port 5. Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 -- 1 -- 1 -- 6 -- 1 -- 1 -- Reserved bits 5 -- 1 -- 1 -- 4 -- 1 -- 1 -- 3 1 -- 0 W 2 1 -- 0 W 1 1 -- 0 W 0 1 -- 0 W P5 3 DDR P5 2 DDR P5 1 DDR P5 0 DDR Port 5 data direction 3 to 0 These bits select input or output for port 5 pins * Modes 1 to 4 (Expanded Modes with On-Chip ROM Disabled) P5DDR values are fixed at 1 and cannot be modified. Port 5 functions as an address bus. The reserved bits (P57DDR to P54DDR) are also fixed at 1. * Modes 5 and 6 (Expanded Modes with On-Chip ROM Enabled) Following a reset, port 5 is an input port. A pin in port 5 becomes an address output pin if the corresponding P5DDR bit is set to 1, and an input port if this bit is cleared to 0. * Mode 7 (Single-Chip Mode) Port 5 functions as an input/output port. A pin in port 5 becomes an output port if the corresponding P5DDR bit is set to 1, and an input port if this bit is cleared to 0. Rev. 2.0, 03/01, page 263 of 822 P5DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P5DDR is initialized to H'F0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting, so if a P5DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 5 Data Register (P5DR) P5DR is an 8-bit readable/writable register that stores output data for pins P53 to P50. When a bit in P5DDR is set to 1, if port 5 is read the value of the corresponding P5DR bit is returned. When a bit in P5DDR is cleared to 0, if port 5 is read the corresponding pin level is read. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 P5 3 0 R/W 2 P5 2 0 R/W 1 P5 1 0 R/W 0 P5 0 0 R/W Reserved bits Port 5 data 3 to 0 These bits store data for port 5 pins Bits 7 to 4 are reserved. They cannot be modified and are always read as 1. P5DR is initialized to H'F0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Port 5 Input Pull-Up MOS Control Register (P5PCR) Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W P5 3 PCR P5 2 PCR P5 1 PCR P5 0 PCR Reserved bits Port 5 input pull-up MOS control 3 to 0 These bits control input pull-up MOS transistors built into port 5 P5PCR is an 8-bit readable/writable register that controls the MOS input pull-up MOS transistors in port 5. In modes 5 to 7, when a P5DDR bit is cleared (selecting the input port function), if the corresponding bit in P5PCR is set up 1, the input pull-up MOS transistor is turned on. Rev. 2.0, 03/01, page 264 of 822 P5PCR is initialized to H'F0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Table 9.9 summarizes the states of the input pull-ups MOS in each mode. Table 9.9 Mode 1 2 3 4 5 6 7 Legend Off: The input pull-up MOS transistor is always off. On/off: The input pull-up MOS transistor is on if P5PCR = 1 and P5DDR = 0. Otherwise, it is off. Off Off On/off On/off Input Pull-Up MOS Transistor States (Port 5) Reset Off Hardware Standby Mode Off Software Standby Mode Off Other Modes Off Rev. 2.0, 03/01, page 265 of 822 9.7 9.7.1 Port 6 Overview Port 6 is a 7-bit input/output port that is also used for input and output of bus control signals (/:5, +:5, 5', $6, %$&., %5(4, and :$,7). When DRAM is connected to area 3, /:5, +:5, and 5' also function as /:, 8:, and &$6, or /&$6, 8&$6, and :(, respectively. For details see section 7, Refresh Controller. Figure 9.6 shows the pin configuration of port 6. In modes 1 to 6 (expanded modes) the pin functions are /:5, +:5, 5', $6, P62/%$&., P61/%5(4, and P60/:$,7. See table 9.11 for the method of selecting the pin states. In mode 7 (single-chip mode) port 6 is a generic input/output port. Pins in port 6 can drive one TTL load and a 30-pF capacitive load. They can also drive a darlington transistor pair. Port 6 pins P6 6 / P6 5 / P6 4 / Port 6 P6 3 / P6 2 / P6 1 / P6 0 / Modes 1 to 6 (expanded modes) (output) (output) (output) (output) P6 2 (input/output)/ P6 1 (input/output)/ P6 0 (input/output)/ (output) (input) (input) Mode 7 (single-chip mode) P6 6 (input/output) P6 5 (input/output) P6 4 (input/output) P6 3 (input/output) P6 2 (input/output) P6 1 (input/output) P6 0 (input/output) Figure 9.6 Port 6 Pin Configuration Rev. 2.0, 03/01, page 266 of 822 9.7.2 Register Configuration Table 9.10 summarizes the registers of port 6. Table 9.10 Port 6 Registers Initial Value Address* H'FFC9 H'FFCB Name Port 6 data direction register Port 6 data register Abbreviation P6DDR P6DR R/W W R/W Mode 1 to 5 H'F8 H'80 Mode 6, 7 H'80 H'80 Note: * Lower 16 bits of the address. Port 6 Data Direction Register (P6DDR) P6DDR is an 8-bit write-only register that can select input or output for each pin in port 6. Bit Initial value Read/Write 7 -- 1 -- Reserved bit 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W P6 6 DDR P6 5 DDR P6 4 DDR P6 3 DDR P6 2 DDR P6 1 DDR P6 0 DDR Port 6 data direction 6 to 0 These bits select input or output for port 6 pins * Modes 1 to 6 (Expanded Modes) P66 to P63 function as bus control output pins (/:5, +:5, 5', $6). P62 to P60 are generic input/output pins, functioning as output port when bits P62DDR to P60DDR are set to 1 and input port when these bits are cleared to 0. * Mode 7 (Single-Chip Mode) Port 6 is a generic input/output port. A pin in port 6 becomes an output port if the corresponding P6DDR bit is set to 1, and an input port if this bit is cleared to 0. Bit 7 is reserved. P6DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P6DDR is initialized to H'80 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a P6DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Rev. 2.0, 03/01, page 267 of 822 Port 6 Data Register (P6DR) Bit Initial value Read/Write 7 -- 1 -- Reserved bit 6 P6 6 0 R/W 5 P6 5 0 R/W 4 P6 4 0 R/W 3 P6 3 0 R/W 2 P6 2 0 R/W 1 P6 1 0 R/W 0 P6 0 0 R/W Port 6 data 6 to 0 These bits store data for port 6 pins P6DR is an 8-bit readable/writable register that stores output data for pins P66 to P60. When this register is read, the pin logic level is read for a bit with the corresponding P6DDR bit cleared to 0, and the P6DR value is read for a bit with the corresponding P6DDR bit set to 1. Bit 7 is reserved, cannot be modified, and always read as 1. P6DR is initialized to H'80 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 268 of 822 Table 9.11 Pin P66//:5 Port 6 Pin Functions in Modes 1 to 6 Pin Functions and Selection Method Functions as follows regardless of P66DDR P66DDR Pin function 0 /:5 output 1 P65/+:5 Functions as follows regardless of P65DDR P65DDR Pin function 0 +:5 output 1 P64/5' Functions as follows regardless of P64DDR P64DDR Pin function 0 5' output 1 P63/$6 Functions as follows regardless of P63DDR P63DDR Pin function 0 $6 output 1 P62/%$&. Bit BRLE in BRCR and bit P62DDR select the pin function as follows BRLE P62DDR Pin function 0 P62 input 0 1 P62 output 1 -- %$&. output P61/%5(4 Bit BRLE in BRCR and bit P61DDR select the pin function as follows BRLE P61DDR Pin function 0 P61 input 0 1 P61 output 1 -- %5(4 input P60/:$,7 Bits WCE7 to WCE0 in WCER, bit WMS1 in WCR, and bit P60DDR select the pin function as follows WCER WMS1 P60DDR Pin function 0 P60 input 0 1 P60 output All 1s 1 0* :$,7 input Not all 1s -- 0* Note: * Do not set bit P60DDR to 1. Rev. 2.0, 03/01, page 269 of 822 9.8 9.8.1 Port 7 Overview Port 7 is an 8-bit input port that is also used for analog input to the A/D converter and analog output from the D/A converter. The pin functions are the same in all operating modes. Figure 9.7 shows the pin configuration of port 7. Port 7 pins P77 (input)/AN 7 (input)/DA 1 (output) P76 (input)/AN 6 (input)/DA 0 (output) P75 (input)/AN 5 (input) Port 7 P74 (input)/AN 4 (input) P73 (input)/AN 3 (input) P72 (input)/AN 2 (input) P71 (input)/AN 1 (input) P70 (input)/AN 0 (input) Figure 9.7 Port 7 Pin Configuration Rev. 2.0, 03/01, page 270 of 822 9.8.2 Register Configuration Table 9.12 summarizes the port 7 register. Port 7 is an input-only port, so it has no data direction register. Table 9.12 Port 7 Data Register Address* H'FFCE Name Port 7 data register Abbreviation P7DR R/W R Initial Value Undetermined Note: * Lower 16 bits of the address. Port 7 Data Register (P7DR) Bit Initial value Read/Write 7 P77 --* R 6 P76 --* R 5 P75 --* R 4 P74 --* R 3 P73 --* R 2 P72 --* R 1 P71 --* R 0 P70 --* R Note: * Determined by pins P7 7 to P70 . When port 7 is read, the pin levels are always read. Rev. 2.0, 03/01, page 271 of 822 9.9 9.9.1 Port 8 Overview Port 8 is a 5-bit input/output port that is also used for &63 to &60 output, 5)6+ output, and ,543 to ,540 input. Figure 9.8 shows the pin configuration of port 8. In modes 1 to 6 (expanded modes), port 8 can provide &63 to &60 output, RFSH output, and ,543 to ,540 input. See table 9.14 for the selection of pin functions in expanded modes. In mode 7 (single-chip mode), port 8 can provide ,543 to ,540 input. See table 9.15 for the selection of pin functions in single-chip mode. The ,543 to ,540 functions are selected by IER settings, regardless of whether the pin is used for input or output. For details see section 5, Interrupt Controller. Pins in port 8 can drive one TTL load and a 90-pF capacitive load. They can also drive a darlington transistor pair. Pins P82 to P80 have Schmitt-trigger inputs. Port 8 pins Pin functions in modes 1 to 6 (expanded modes) P84 (input)/ 3 2 1 0 1 2 3 P84 / P83 / Port 8 P82 / P81 / P80 / 0 1/ 2/ 3/ (output) (output)/ (output)/ (output)/ 3 2 1 P83 (input)/ P82 (input)/ P81 (input)/ 0 (input) (input) (input) 0 / P80 (input/output)/ (output)/ (input) Pin functions in mode 7 (single-chip mode) P84 /(input/output) P83 /(input/output)/ P82 /(input/output)/ P81 /(input/output)/ P80 /(input/output)/ 3 2 1 0 (input) (input) (input) (input) Figure 9.8 Port 8 Pin Configuration Rev. 2.0, 03/01, page 272 of 822 9.9.2 Register Configuration Table 9.13 summarizes the registers of port 8. Table 9.13 Port 8 Registers Initial Value Address* H'FFCD H'FFCF Name Port 8 data direction register Port 8 data register Abbreviation P8DDR P8DR R/W W R/W Mode 1 to 4 H'F0 H'E0 Mode 5 to 7 H'E0 H'E0 Note: * Lower 16 bits of the address. Port 8 Data Direction Register (P8DDR) P8DDR is an 8-bit write-only register that can select input or output for each pin in port 8. Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 -- 1 -- 1 -- 6 -- 1 -- 1 -- 5 -- 1 -- 1 -- 4 1 W 0 W 3 0 W 0 W 2 0 W 0 W 1 0 W 0 W 0 0 W 0 W P8 4 DDR P8 3 DDR P8 2 DDR P8 1 DDR P8 0 DDR Reserved bits Port 8 data direction 4 to 0 These bits select input or output for port 8 pins * Modes 1 to 6 (Expanded Modes) When bits in P8DDR bit are set to 1, P84 to P81 become &60 to &63 output pins. When bits in P8DDR are cleared to 0, the corresponding pins become input ports. In modes 1 to 4 (expanded modes with on-chip ROM disabled), following a reset only &60 is output. The other three pins are input ports. In modes 5 and 6 (expanded modes with on-chip ROM enabled), following a reset all four pins are input ports. When the refresh controller is enabled, P80 is used unconditionally for 5)6+ output. When the refresh controller is disabled, P80 becomes a generic input/output port according to the P8DDR setting. For details see table 9.15. * Mode 7 (Single-Chip Mode) Port 8 is a generic input/output port. A pin in port 8 becomes an output port if the corresponding P8DDR bit is set to 1, and an input port if this bit is cleared to 0. Rev. 2.0, 03/01, page 273 of 822 P8DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P8DDR is initialized to H'E0 or H'F0 by a reset and in hardware standby mode. The reset value depends on the operating mode. In software standby mode P8DDR retains its previous setting. If a P8DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Port 8 Data Register (P8DR) P8DR is an 8-bit readable/writable register that stores output data for pins P84 to P80. When a bit in P8DDR is set to 1, if port 8 is read the value of the corresponding P8DR bit is returned. When a bit in P8DDR is cleared to 0, if port 8 is read the corresponding pin level is read. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- Reserved bits 5 -- 1 -- 4 P8 4 0 R/W 3 P8 3 0 R/W 2 P8 2 0 R/W 1 P8 1 0 R/W 0 P8 0 0 R/W Port 8 data 4 to 0 These bits store data for port 8 pins Bits 7 to 5 are reserved. They cannot be modified and always are read as 1. P8DR is initialized to H'E0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 274 of 822 Table 9.14 Port 8 Pin Functions in Modes 1 to 6 Pin P84/&60 Pin Functions and Selection Method Bit P84DDR selects the pin function as follows P84DDR Pin function P83/&61/,543 0 P84 input 1 &60 output Bit P83DDR selects the pin function as follows P83DDR Pin function 0 P83 input ,543 input 1 &61 output P82/&62/,542 Bit P82DDR selects the pin function as follows P82DDR Pin function 0 P82 input ,542 input 1 &62 output P81/&63/,541 Bit P81DDR selects the pin function as follows P81DDR Pin function 0 P81 input ,541 input 1 &63 output P80/5)6+/,540 Bit RFSHE in RFSHCR and bit P80DDR select the pin function as follows RFSHE P80DDR Pin function 0 P80 input 0 1 P80 output ,540 input 1 -- 5)6+ output Rev. 2.0, 03/01, page 275 of 822 Table 9.15 Port 8 Pin Functions in Mode 7 Pin P84 Pin Functions and Selection Method Bit P84DDR selects the pin function as follows P84DDR Pin function P83/,543 0 P84 input 1 P84 output Bit P83DDR selects the pin function as follows P83DDR Pin function 0 P83 input ,543 input 1 P83 output P82/,542 Bit P82DDR selects the pin function as follows P82DDR Pin function 0 P82 input ,542 input 1 P82 output P81/,541 Bit P81DDR selects the pin function as follows P81DDR Pin function 0 P81 input ,541 input 1 P81 output P80/,540 Bit P80DDR select the pin function as follows P80DDR Pin function 0 P80 input ,540 input 1 P80 output Rev. 2.0, 03/01, page 276 of 822 9.10 9.10.1 Port 9 Overview Port 9 is a 6-bit input/output port that is also used for input and output (TxD0, TxD1, RxD0, RxD1, SCK0, SCK1) by serial communication interface channels 0 and 1 (SCI0 and SCI1), and for ,545 and ,544 input. See table 9.17 for the selection of pin functions. The ,545 and ,544 functions are selected by IER settings, regardless of whether the pin is used for input or output. For details see section 5, Interrupt Controller. Port 9 has the same set of pin functions in all operating modes. Figure 9.9 shows the pin configuration of port 9. Pins in port 9 can drive one TTL load and a 30-pF capacitive load. They can also drive a darlington transistor pair. Port 9 pins P95 (input/output)/SCK 1 (input/output)/ P94 (input/output)/SCK 0 (input/output)/ Port 9 P93 (input/output)/RxD1 (input) P92 (input/output)/RxD0 (input) P91 (input/output)/TxD1 (output) P90 (input/output)/TxD0 (output) (input) (input) 5 4 Figure 9.9 Port 9 Pin Configuration Rev. 2.0, 03/01, page 277 of 822 9.10.2 Register Configuration Table 9.16 summarizes the registers of port 9. Table 9.16 Port 9 Registers Address* H'FFD0 H'FFD2 Name Port 9 data direction register Port 9 data register Abbreviation P9DDR P9DR R/W W R/W Initial Value H'C0 H'C0 Note: * Lower 16 bits of the address. Port 9 Data Direction Register (P9DDR) P9DDR is an 8-bit write-only register that can select input or output for each pin in port 9. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W P9 5 DDR P9 4 DDR P9 3 DDR P9 2 DDR P9 1 DDR P9 0 DDR Reserved bits Port 9 data direction 5 to 0 These bits select input or output for port 9 pins A pin in port 9 becomes an output port if the corresponding P9DDR bit is set to 1, and an input port if this bit is cleared to 0. P9DDR is a write-only register. Its value cannot be read. All bits return 1 when read. P9DDR is initialized to H'C0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a P9DDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Rev. 2.0, 03/01, page 278 of 822 Port 9 Data Register (P9DR) P9DR is an 8-bit readable/writable register that stores output data for pins P95 to P90. When a bit in P9DDR is set to 1, if port 9 is read the value of the corresponding P9DR bit is returned. When a bit in P9DDR is cleared to 0, if port 9 is read the corresponding pin level is read. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 P9 5 0 R/W 4 P9 4 0 R/W 3 P9 3 0 R/W 2 P9 2 0 R/W 1 P9 1 0 R/W 0 P9 0 0 R/W Reserved bits Port 9 data 5 to 0 These bits store data for port 9 pins Bits 7 and 6 are reserved. They cannot be modified and are always read as 1. P9DR is initialized to H'C0 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 279 of 822 Table 9.17 Port 9 Pin Functions Pin P95/SCK1/,545 Pin Functions and Selection Method Bit C/$ in SMR of SCI1, bits CKE0 and CKE1 in SCR of SCI1, and bit P95DDR select the pin function as follows CKE1 C/$ CKE0 P95DDR Pin function 0 P95 input 0 1 P95 output 0 1 -- SCK1 output ,545 input P94/SCK0/,544 Bit C/$ in SMR of SCI0, bits CKE0 and CKE1 in SCR of SCI0, and bit P94DDR select the pin function as follows CKE1 C/$ CKE0 P94DDR Pin function 0 P94 input 0 1 P94 output 0 1 -- SCK0 output ,544 input P93/RxD1 Bit RE in SCR of SCI1 and bit P93DDR select the pin function as follows RE P93DDR Pin function P92/RxD0 0 P93 input 0 1 P93 output 1 -- RxD1 input 0 1 -- -- SCK0 output 1 -- -- -- SCK0 input 0 1 -- -- SCK1 output 1 -- -- -- SCK1 input Bit RE in SCR of SCI0, bit SMIF in SCMR, and bit P92DDR select the pin function as follows SMIF RE P92DDR Pin function 0 P92 input 0 1 P92 output 0 1 -- RxD0 input 1 -- -- RxD0 input Rev. 2.0, 03/01, page 280 of 822 Pin P91/TxD1 Pin Functions and Selection Method Bit TE in SCR of SCI1 and bit P91DDR select the pin function as follows TE P91DDR Pin function 0 P91 input 0 1 P91 output 1 -- TxD1 output P90/TxD0 Bit TE in SCR of SCI0, bit SMIF in SCMR, and bit P90DDR select the pin function as follows SMIF TE P90DDR Pin function 0 P90 input 0 1 P90 output 0 1 -- TxD0 output 1 -- -- TxD0 output* Note: * Functions as the TxD0 output pin, but there are two states: one in which the pin is driven, and another in which the pin is at high-impedance. Rev. 2.0, 03/01, page 281 of 822 9.11 9.11.1 Port A Overview Port A is an 8-bit input/output port that is also used for output (TP7 to TP0) from the programmable timing pattern controller (TPC), input and output (TIOCB2, TIOCA2, TIOCB1, TIOCA1, TIOCB0, TIOCA0, TCLKD, TCLKC, TCLKB, TCLKA) by the 16-bit integrated timer unit (ITU), output (7(1'1, 7(1'0) from the DMA controller (DMAC), &64 to &66 output, and address output (A23 to A20). A reset or hardware standby leaves port A as an input port, except that in modes 3, 4, and 6, one pin is always used for A20 output. Usage of pins for TPC, ITU, and DMAC input and output is described in the sections on those modules. For output of address bits A23 to A21 in modes 3, 4, and 6, see section 6.2.5, Bus Release Control Register (BRCR). For output of &64 to &66 in modes 1 to 6, see section 6.3.2, Chip Select Signals. Pins not assigned to any of these functions are available for generic input/output. Figure 9.10 shows the pin configuration of port A. Pins in port A can drive one TTL load and a 30-pF capacitive load. They can also drive a darlington transistor pair. Port A has Schmitt-trigger inputs. Rev. 2.0, 03/01, page 282 of 822 Port A pins PA 7/TP7 /TIOCB2 /A 20 PA 6/TP6 /TIOCA2 /A21/CS4 PA 5/TP5 /TIOCB1 /A22/CS5 PA 4/TP4 /TIOCA1 /A23/CS6 Port A PA 3/TP3 /TIOCB 0 /TCLKD PA 2/TP2 /TIOCA 0 /TCLKC PA 1/TP1 /TEND1 /TCLKB PA 0/TP0 /TEND0 /TCLKA Pin functions in modes 1, 2, and 5 PA 7 (input/output)/TP7 (output)/TIOCB 2 (input/output) PA 6 (input/output)/TP6 (output)/TIOCA 2 (input/output)/CS4 (output) PA 5 (input/output)/TP5 (output)/TIOCB 1 (input/output)/CS5(output) PA 4 (input/output)/TP4 (output)/TIOCA 1 (input/output)/CS6(output) PA 3 (input/output)/TP3 (output)/TIOCB 0 (input/output)/TCLKD (input) PA 2 (input/output)/TP2 (output)/TIOCA 0 (input/output)/TCLKC (input) PA 1 (input/output)/TP1 (output)/TEND 1 (output)/TCLKB (input) PA 0 (input/output)/TP0 (output)/TEND 0 (output)/TCLKA (input) Pin functions in modes 3, 4, and 6 A20 (output) PA 6 (input/output)/TP6 (output)/TIOCA 2 (input/output)/A 21 (output)/CS4 (output) PA 5 (input/output)/TP5 (output)/TIOCB 1 (input/output)/A 22 (output)/CS5 (output) PA 4 (input/output)/TP4 (output)/TIOCA 1 (input/output)/A 23 (output)/CS6 (output) PA 3 (input/output)/TP3 (output)/TIOCB 0 (input/output)/TCLKD (input) PA 2 (input/output)/TP2 (output)/TIOCA 0 (input/output)/TCLKC (input) PA 1 (input/output)/TP1 (output)/TEND 1 (output)/TCLKB (input) PA 0 (input/output)/TP0 (output)/TEND 0 (output)/TCLKA (input) Pin functions in mode 7 PA7 (input/output)/TP7 (output)/TIOCB2 (input/output) PA6 (input/output)/TP6 (output)/TIOCA2 (input/output) PA5 (input/output)/TP5 (output)/TIOCB1 (input/output) PA4 (input/output)/TP4 (output)/TIOCA1 (input/output) PA3 (input/output)/TP3 (output)/TIOCB0 (input/output)/TCLKD (input) PA2 (input/output)/TP2 (output)/TIOCA0 (input/output)/TCLKC (input) PA1 (input/output)/TP1 (output)/TEND1 (output)/TCLKB (input) PA0 (input/output)/TP0 (output)/TEND0 (output)/TCLKA (input) Figure 9.10 Port A Pin Configuration Rev. 2.0, 03/01, page 283 of 822 9.11.2 Register Configuration Table 9.18 summarizes the registers of port A. Table 9.18 Port A Registers Initial Value Address* H'FFD1 H'FFD3 Name Port A data direction register Port A data register Abbreviation PADDR PADR R/W W R/W Modes 1, 2, 5 and 7 H'00 H'00 Modes 3, 4, and 6 H'80 H'00 Note: * Lower 16 bits of the address. Port A Data Direction Register (PADDR) PADDR is an 8-bit write-only register that can select input or output for each pin in port A. When pins are used for TPC output, the corresponding PADDR bits must also be set. Bit Modes 3, 4, and 6 Modes 1, 2, 5, and 7 Initial value Initial value 7 1 0 6 0 W 0 W 5 0 W 0 W 4 0 W 0 W 3 0 W 0 W 2 0 W 0 W 1 0 W 0 W 0 0 W 0 W PA7 DDR PA6 DDR PA5 DDR PA4 DDR PA3 DDR PA2 DDR PA1 DDR PA0 DDR Read/Write -- Read/Write W Port A data direction 7 to 0 These bits select input or output for port A pins A pin in port A becomes an output pin if the corresponding PADDR bit is set to 1, and an input pin if this bit is cleared to 0. In modes 3, 4, and 6, PA7DDR is fixed at 1 and PA7 functions as an address output pin. PADDR is a write-only register. Its value cannot be read. All bits return 1 when read. PADDR is initialized to H'00 by a reset and in hardware standby mode in modes 1, 2, 5, and 7. It is initialized to H'80 by a reset and in hardware standby mode in modes 3, 4, and 6. In software standby mode it retains its previous setting. If a PADDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Rev. 2.0, 03/01, page 284 of 822 Port A Data Register (PADR) PADR is an 8-bit readable/writable register that stores output data for pins PA7 to PA0. When a bit in PADDR is set to 1, if port A is read the value of the corresponding PADR bit is returned. When a bit in PADDR is cleared to 0, if port A is read the corresponding pin level is read. Bit Initial value Read/Write 7 PA 7 0 R/W 6 PA 6 0 R/W 5 PA 5 0 R/W 4 PA 4 0 R/W 3 PA 3 0 R/W 2 PA 2 0 R/W 1 PA 1 0 R/W 0 PA 0 0 R/W Port A data 7 to 0 These bits store data for port A pins PADR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 285 of 822 9.11.3 Pin Functions Table 9.19 describes the selection of pin functions. Table 9.19 Port A Pin Functions Pin Pin Functions and Selection Method PA7/TP7/ The mode setting, ITU channel 2 settings (bit PWM2 in TMDR and bits IOB2 to IOB0 in TIOCB2/A20 TIOR2), bit NDER7 in NDERA, and bit PA7DDR in PADDR select the pin function as follows Mode ITU channel 2 settings PA7DDR NDER7 Pin function -- -- TIOCB2 output 1, 2, 5, 7 (1) in table below 0 -- PA7 input 1 0 PA7 output TIOCB2 input* (2) in table below 1 1 TP7 output 3, 4, 6 -- -- -- A20 output Note: * TIOCB2 input when IOB2 = 1 and PWM2 = 0. ITU channel 2 settings IOB2 IOB1 IOB0 0 0 (2) 0 0 1 (1) (2) 1 1 -- -- -- Rev. 2.0, 03/01, page 286 of 822 Pin PA6/TP6/ TIOCA2/ A21/&64 Pin Functions and Selection Method The mode setting, bit A21E in BRCR, bit CS4E in CSCR, ITU channel 2 settings (bit PWM2 in TMDR and bits IOA2 to IOA0 in TIOR2), bit NDER6 in NDERA, and bit PA6DDR in PADDR select the pin function as follows Mode CS4E A21E ITU channel 2 settings PA6DDR NDER6 Pin function (1) in table below -- -- 0 -- 1 0 PA6 put 1 1 TP6 output -- -- 1, 2, 5 0 -- (2) in table below 1 -- -- (1) in table below -- -- 0 -- 1 0 PA6 put 1 1 TP6 output -- -- A21 output -- -- 1 (2) in table below 3, 4, 6 0 0 -- 1 -- -- (1) in table below -- -- 0 -- 1 0 PA6 put 1 1 TP6 output 7 -- -- (2) in table below TIOCA2 PA6 &64 TIOCA2 PA6 output &64 TIOCA2 PA6 output output input out- output input out- output input out- TIOCA2 input* Note: * TIOCA2 input when IOA2 = 1. ITU channel 2 settings PWM2 IOA2 IOA1 IOA0 0 0 0 0 1 0 (2) (1) TIOCA2 input* TIOCA2 input* (2) (1) 1 1 1 -- -- -- -- -- -- Rev. 2.0, 03/01, page 287 of 822 Pin PA5/TP5/ TIOCB1/ A22/&65 Pin Functions and Selection Method The mode setting, bit A22E in BRCR, bit CS5E in CSCR, ITU channel 1 settings (bit PWM1 in TMDR and bits IOB2 to IOB0 in TIOR1), bit NDER5 in NDERA, and bit PA5DDR in PADDR select the pin function as follows Mode CS5E A22E ITU channel 1 settings PA5DDR NDER5 Pin function (1) in table below -- -- 0 -- 1 0 PA5 put 1 1 TP5 output -- -- 1, 2, 5 0 -- (2) in table below 1 -- -- (1) in table below -- -- 0 -- 1 0 PA5 put 1 1 TP5 output -- -- A22 output -- -- 1 (2) in table below 3, 4, 6 0 0 -- 1 -- -- (1) in table below -- -- 0 -- 1 0 PA5 put 1 1 TP5 output 7 -- -- (2) in table below TIOCB1 PA5 CS5 TIOCB1 PA5 output CS5 TIOCB1 PA5 output output input out- output input out- output input out- TIOCB1 input* Note: * TIOCB1 input when IOB2 = 1 and PWM1 = 0. ITU channel 1 settings IOB2 IOB1 IOB0 0 0 0 0 1 (2) TIOCB1 input* TIOCB1 input* (1) (2) 1 1 -- -- -- Rev. 2.0, 03/01, page 288 of 822 Pin PA4/TP4/ TIOCA1/ A23/&66 Pin Functions and Selection Method The mode setting, bit A23E in BRCR, bit CS6E in CSCR, ITU channel 1 settings (bit PWM1 in TMDR and bits IOA2 to IOA0 in TIOR1), bit NDER4 in NDERA, and bit PA4DDR in PADDR select the pin function as follows Mode CS6E A23E ITU channel 2 settings (1) in table below -- -- 0 -- 1 0 PA4 put 1 1 TP4 output -- -- 1, 2, 5 0 -- (2) in table below 1 -- -- (1) in table below -- -- 0 -- 1 0 PA4 put 1 1 TP4 output -- -- A23 output -- -- 1 (2) in table below 3, 4, 6 0 0 -- 1 -- -- (1) in table below -- -- 0 -- 1 0 PA4 put 1 1 TP4 output 7 -- -- (2) in table below PA4DDR NDER4 Pin function TIOCA1 PA4 &66 TIOCA1 PA4 output &66 TIOCA1 PA4 output output input out- output input out- output input out- TIOCA1 input* Note: * TIOCA1 input when IOA2 = 1. ITU channel 1 settings PWM1 IOA2 IOA1 IOA0 0 0 0 0 1 0 (2) (1) TIOCA1 input* TIOCA1 input* (2) (1) 1 1 1 -- -- -- -- -- -- Rev. 2.0, 03/01, page 289 of 822 Pin PA3/TP3/ TIOCB0/ TCLKD Pin Functions and Selection Method ITU channel 0 settings (bit PWM0 in TMDR and bits IOB2 to IOB0 in TIOR0), bits TPSC2 to TPSC0 in TCR4 to TCR0, bit NDER3 in NDERA, and bit PA3DDR in PADDR select the pin function as follows ITU channel 0 settings PA3DDR NDER3 Pin function (1) in table below -- -- TIOCB0 output 0 -- PA3 input (2) in table below 1 0 PA3 output TIOCB0 input* TCLKD input* 2 1 1 1 TP3 output Notes: 1. TIOCB0 input when IOB2 = 1 and PWM0 = 0. 2. TCLKD input when TPSC2 = TPSC1 = TPSC0 = 1 in any of TCR4 to TCR0. ITU channel 0 settings IOB2 IOB1 IOB0 0 0 (2) 0 0 1 1 -- (1) (2) 1 -- -- Rev. 2.0, 03/01, page 290 of 822 Pin PA2/TP2/ TIOCA0/ TCLKC Pin Functions and Selection Method ITU channel 0 settings (bit PWM0 in TMDR and bits IOA2 to IOA0 in TIOR0), bits TPSC2 to TPSC0 in TCR4 to TCR0, bit NDER2 in NDERA, and bit PA2DDR in PADDR select the pin function as follows ITU channel 0 settings PA2DDR NDER2 Pin function (1) in table below -- -- IOCA0 output 0 -- PA2 input (2) in table below 1 0 PA2 output TIOCA0 input* TCLKC input* 2 1 1 1 TP2 output Notes: 1. TIOCA0 input when IOA2 = 1. 2. TCLKC input when TPSC2 = TPSC1 = 1 and TPSC0 = 0 in any of TCR4 to TCR0. ITU channel 0 settings PWM0 IOA2 IOA1 IOA0 0 0 0 0 1 1 -- (2) (1) 0 1 -- -- (2) (1) 1 -- -- -- Rev. 2.0, 03/01, page 291 of 822 Pin PA1/TP1/ TCLKB/ 7(1'1 Pin Functions and Selection Method DMAC channel 1 settings (bits DTS2/1/0A and DTS2/1/0B in DTCR1A and DTCR1B), bit NDER1 in NDERA, and bit PA1DDR in PADDR select the pin function as follows DMAC channel 1 settings PA1DDR NDER1 Pin function (1) in table below -- -- 7(1'1 output 0 -- PA1 input (2) in table below 1 0 PA1 output TCLKB input* Note: * TCLKB input when MDF = 1 in TMDR, or when TPSC2 = 1, TPSC1 = 0, and TPSC0 = 1 in any of TCR4 to TCR0. DMAC channel 1 settings DTS2A, DTS1A DTS0A DTS2B DTS1B 0 -- (2) Not both 1 -- 1 0 1 1 0 0 -- 0 1 -- (1) (2) (1) (2) Both 1 1 0 -- 1 1 0 1 1 1 (1) 1 1 TP1 output Rev. 2.0, 03/01, page 292 of 822 Pin PA0/TP0/ TCLKA/ 7(1'0 Pin Functions and Selection Method DMAC channel 0 settings (bits DTS2/1/0A and DTS2/1/0B in DTCR0A and DTCR0B), bit NDER0 in NDERA, and bit PA0DDR in PADDR select the pin function as follows DMAC channel 0 settings PA0DDR NDER0 Pin function (1) in table below -- -- 7(1'0 output 0 -- PA0 input (2) in table below 1 0 PA0 output TCLKA input* Note: * TCLKA input when MDF = 1 in TMDR, or when TPSC2 = 1 and TPSC1 = 0 in any of TCR4 to TCR0. DMAC channel 0 settings DTS2A, DTS1A DTS0A DTS2B DTS1B 0 -- (2) Not both 1 -- 1 0 1 1 0 0 -- 0 1 -- (1) (2) (1) (2) Both 1 1 0 -- 1 1 0 1 1 1 (1) 1 1 TP0 output Rev. 2.0, 03/01, page 293 of 822 9.12 9.12.1 Port B Overview Port B is an 8-bit input/output port that is also used for output (TP15 to TP8) from the programmable timing pattern controller (TPC), input/output (TIOCB4, TIOCB3, TIOCA4, TIOCA3) and output (TOCXB4, TOCXA4) by the 16-bit integrated timer unit (ITU), input ('5(41, '5(40) to the DMA controller (DMAC), $'75* input to the A/D converter, and &67 output. A reset or hardware standby leaves port B as an input port. Usage of pins for TPC, ITU, DMAC, and A/D converter input and output is described in the sections on those modules. For output of &67 in modes 1 to 6, see section 6.3.2, Chip Select Signals. Pins not assigned to any of these functions are available for generic input/output. Figure 9.11 shows the pin configuration of port B. Pins in port B can drive one TTL load and a 30-pF capacitive load. They can also drive an LED or darlington transistor pair. Pins PB3 to PB0 have Schmitt-trigger inputs. Rev. 2.0, 03/01, page 294 of 822 Port B pins PB7/TP15/ PB6/TP14/ 1/ 0/ 7 PB5/TP13/TOCXB4 PB4/TP12/TOCXA4 Port B PB3/TP11/TIOCB4 PB2/TP10/TIOCA4 PB1/TP9/TIOCB3 PB0/TP8/TIOCA3 Pin functions in modes 1 to 6 PB7 (input/output)/TP15 (output)/ PB6 (input/output)/TP14 (output)/ 1 0 (input)/ (input)/ 7 (input) (output) PB5 (input/output)/TP13 (output)/TOCXB4 (output) PB4 (input/output)/TP12 (output)/TOCXA4 (output) PB3 (input/output)/TP11 (output)/TIOCB4 (input/output) PB2 (input/output)/TP10 (output)/TIOCA4 (input/output) PB1 (input/output)/TP9 (output)/TIOCB3 (input/output) PB0 (input/output)/TP8 (output)/TIOCA3 (input/output) Pin functions in mode 7 PB7 (input/output)/TP15 (output)/ PB6 (input/output)/TP14 (output)/ 1 0 (input)/ (input) (input) PB5 (input/output)/TP13 (output)/TOCXB4 (output) PB4 (input/output)/TP12 (output)/TOCXA4 (output) PB3 (input/output)/TP11 (output)/TIOCB4 (input/output) PB2 (input/output)/TP10 (output)/TIOCA4 (input/output) PB1 (input/output)/TP9 (output)/TIOCB3 (input/output) PB0 (input/output)/TP8 (output)/TIOCA3 (input/output) Figure 9.11 Port B Pin Configuration Rev. 2.0, 03/01, page 295 of 822 9.12.2 Register Configuration Table 9.20 summarizes the registers of port B. Table 9.20 Port B Registers Address* H'FFD4 H'FFD6 Name Port B data direction register Port B data register Abbreviation PBDDR PBDR R/W W R/W Initial Value H'00 H'00 Note: * Lower 16 bits of the address. Port B Data Direction Register (PBDDR) PBDDR is an 8-bit write-only register that can select input or output for each pin in port B. When pins are used for TPC output, the corresponding PBDDR bits must also be set. Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W PB7 DDR PB6 DDR PB5 DDR PB4 DDR PB3 DDR PB2 DDR PB1 DDR PB0 DDR Port B data direction 7 to 0 These bits select input or output for port B pins A pin in port B becomes an output pin if the corresponding PBDDR bit is set to 1, and an input pin if this bit is cleared to 0. PBDDR is a write-only register. Its value cannot be read. All bits return 1 when read. PBDDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. If a PBDDR bit is set to 1, the corresponding pin maintains its output state in software standby mode. Rev. 2.0, 03/01, page 296 of 822 Port B Data Register (PBDR) PBDR is an 8-bit readable/writable register that stores output data for pins PB7 to PB0. When a bit in PBDDR is set to 1, if port B is read the value of the corresponding PBDR bit is returned. When a bit in PBDDR is cleared to 0, if port B is read the corresponding pin level is read. Bit Initial value Read/Write 7 PB 7 0 R/W 6 PB 6 0 R/W 5 PB 5 0 R/W 4 PB 4 0 R/W 3 PB 3 0 R/W 2 PB 2 0 R/W 1 PB 1 0 R/W 0 PB 0 0 R/W Port B data 7 to 0 These bits store data for port B pins PBDR is initialized to H'00 by a reset and in hardware standby mode. In software standby mode it retains its previous setting. Rev. 2.0, 03/01, page 297 of 822 9.12.3 Pin Functions Table 9.21 describes the selection of pin functions. Table 9.21 Port B Pin Functions Pin PB7/TP15/ '5(41/ $'75* Pin Functions and Selection Method DMAC channel 1 settings (bits DTS2/1/0A and DTS2/1/0B in DTCR1A and DTCR1B), bit TRGE in ADCR, bit NDER15 in NDERB, and bit PB7DDR in PBDDR select the pin function as follows PB7DDR NDER15 Pin function 0 -- PB7 input 1 0 PB7 output '5(41 input*1 $'75* input*2 Notes: 1. '5(41 input under DMAC channel 1 settings (1) in the table below. 2. $'75* input when TRGE = 1. DMAC channel 1 settings DTS2A, DTS1A DTS0A DTS2B DTS1B 0 -- (2) Not both 1 -- 1 0 1 1 0 0 -- 0 1 -- (1) (2) (1) (2) Both 1 1 0 -- 1 1 0 1 1 1 (1) 1 1 TP15 output Rev. 2.0, 03/01, page 298 of 822 Pin PB6/TP14/ '5(40/ &67 Pin Functions and Selection Method Bit CS7E in CSCR, DMAC channel 0 settings (bits DTS2/1/0A and DTS2/1/0B in DTCR0A and DTCR0B), bit NDER14 in NDERB, and bit PB 6DDR in PBDDR select the pin function as follows PB6DDR CS7E NDER14 Pin function 0 0 -- PB6 input 1 0 0 PB6 output '5(40 input* DMAC channel 0 settings DTS2A, DTS1A DTS0A DTS2B DTS1B 0 -- 1 0 1 TP14 output -- 1 -- -- &67 output Note: * '5(40 input under DMAC channel 0 settings (1) in the table below. (2) Not both 1 -- 1 0 1 1 0 0 -- 0 1 -- (1) (2) (1) (2) Both 1 1 0 -- 1 1 0 1 1 1 (1) PB5/TP13/ TOCXB4 ITU channel 4 settings (bit CMD1 in TFCR and bit EXB4 in TOER), bit NDER13 in NDERB, and bit PB5DDR in PBDDR select the pin function as follows EXB4, CMD1 PB5DDR NDER13 Pin function 0 -- PB5 input Not both 1 1 0 PB5 output 1 1 TP13 output Both 1 -- -- TOCXB4 output PB4/TP12/ TOCXA4 ITU channel 4 settings (bit CMD1 in TFCR and bit EXA4 in TOER), bit NDER12 in NDERB, and bit PB4DDR in PBDDR select the pin function as follows EXA4, CMD1 PB4DDR NDER12 Pin function 0 -- PB4 input Not both 1 1 0 PB4 output 1 1 TP12 output Both 1 -- -- TOCXA4 output Rev. 2.0, 03/01, page 299 of 822 Pin PB3/TP11/ TIOCB4 Pin Functions and Selection Method ITU channel 4 settings (bit PWM4 in TMDR, bit CMD1 in TFCR, bit EB4 in TOER, and bits IOB2 to IOB0 in TIOR4), bit NDER11 in NDERB, and bit PB3DDR in PBDDR select the pin function as follows ITU channel 4 settings PB3DDR NDER11 Pin function (1) in table below -- -- TIOCB4 output 0 -- PB3 input (2) in table below 1 0 PB3 output TIOCB4 input* Note: * TIOCB4 input when CMD1 = PWM4 = 0 and IOB2 = 1. ITU channel 4 settings EB4 CMD1 IOB2 IOB1 IOB0 (2) 0 -- -- -- -- 0 0 0 0 0 1 0 0 1 -- 1 -- -- (2) (1) 1 1 -- -- -- (2) (1) 1 1 TP11 output Rev. 2.0, 03/01, page 300 of 822 Pin PB2/TP10/ TIOCA4 Pin Functions and Selection Method ITU channel 4 settings (bit CMD1 in TFCR, bit EA4 in TOER, bit PWM4 in TMDR, and bits IOA2 to IOA0 in TIOR4), bit NDER10 in NDERB, and bit PB2DDR in PBDDR select the pin function as follows ITU channel 4 settings PB2DDR NDER10 Pin function (1) in table below -- -- TIOCA4 output 0 -- PB2 input (2) in table below 1 0 PB2 output TIOCA4 input* Note: * TIOCA4 input when CMD1 = PWM4 = 0 and IOA2 = 1. ITU channel 4 settings EA4 CMD1 PWM4 IOA2 IOA1 IOA0 (2) 0 -- -- -- -- -- 0 0 0 0 0 1 0 0 1 -- 1 -- -- 0 1 -- -- -- (2) (1) 1 1 -- -- -- -- (2) (1) 1 1 TP10 output Rev. 2.0, 03/01, page 301 of 822 Pin PB1/TP9/ TIOCB3 Pin Functions and Selection Method ITU channel 3 settings (bit PWM3 in TMDR, bit CMD1 in TFCR, bit EB3 in TOER, and bits IOB2 to IOB0 in TIOR3), bit NDER9 in NDERB, and bit PB1DDR in PBDDR select the pin function as follows ITU channel 3 settings PB1DDR NDER9 Pin function (1) in table below -- -- TIOCB3 output 0 -- PB1 input (2) in table below 1 0 PB1 output TIOCB3 input* Note: * TIOCB3 input when CMD1 = PWM3 = 0 and IOB2 = 1. ITU channel 3 settings EB3 CMD1 IOB2 IOB1 IOB0 (2) 0 -- -- -- -- 0 0 0 0 0 1 0 0 1 -- 1 -- -- (2) (1) 1 1 -- -- -- (2) (1) 1 1 TP9 output Rev. 2.0, 03/01, page 302 of 822 Pin PB0/TP8/ TIOCA3 Pin Functions and Selection Method ITU channel 3 settings (bit CMD1 in TFCR, bit EA3 in TOER, bit PWM3 in TMDR, and bits IOA2 to IOA0 in TIOR3), bit NDER8 in NDERB, and bit PB0DDR in PBDDR select the pin function as follows ITU channel 3 settings PB0DDR NDER8 Pin function (1) in table below -- -- TIOCA3 output 0 -- PB0 input (2) in table below 1 0 PB0 output TIOCA3 input* Note: * TIOCA3 input when CMD1 = PWM3 = 0 and IOA2 = 1. ITU channel 3 settings EA3 CMD1 PWM3 IOA2 IOA1 IOA0 (2) 0 -- -- -- -- -- 0 0 0 0 0 1 0 0 1 -- 1 -- -- 0 1 -- -- -- (2) (1) 1 1 -- -- -- -- (2) (1) 1 1 TP8 output Rev. 2.0, 03/01, page 303 of 822 Rev. 2.0, 03/01, page 304 of 822 Section 10 16-Bit Integrated Timer Unit (ITU) 10.1 Overview The H8/3052F has a built-in 16-bit integrated timer unit (ITU) with five 16-bit timer channels. When the ITU is not used, it can be independently halted to conserve power. For details see section 20.6, Module Standby Function. 10.1.1 Features ITU features are listed below. * Capability to process up to 12 pulse outputs or 10 pulse inputs * Ten general registers (GRs, two per channel) with independently-assignable output compare or input capture functions * Selection of eight counter clock sources for each channel: Internal clocks: , /2, /4, /8 External clocks: TCLKA, TCLKB, TCLKC, TCLKD * Five operating modes selectable in all channels: Waveform output by compare match Selection of 0 output, 1 output, or toggle output (only 0 or 1 output in channel 2) Input capture function Rising edge, falling edge, or both edges (selectable) Counter clearing function Counters can be cleared by compare match or input capture Synchronization Two or more timer counters (TCNTs) can be preset simultaneously, or cleared simultaneously by compare match or input capture. Counter synchronization enables synchronous register input and output. PWM mode PWM output can be provided with an arbitrary duty cycle. With synchronization, up to five-phase PWM output is possible * Phase counting mode selectable in channel 2 Two-phase encoder output can be counted automatically. * Three additional modes selectable in channels 3 and 4 Reset-synchronized PWM mode If channels 3 and 4 are combined, three-phase PWM output is possible with three pairs of complementary waveforms. Rev. 2.0, 03/01, page 305 of 822  Complementary PWM mode If channels 3 and 4 are combined, three-phase PWM output is possible with three pairs of non-overlapping complementary waveforms. Buffering Input capture registers can be double-buffered. Output compare registers can be updated automatically. * High-speed access via internal 16-bit bus The 16-bit timer counters, general registers, and buffer registers can be accessed at high speed via a 16-bit bus. * Fifteen interrupt sources Each channel has two compare match/input capture interrupts and an overflow interrupt. All interrupts can be requested independently. * Activation of DMA controller (DMAC) Four of the compare match/input capture interrupts from channels 0 to 3 can start the DMAC. * Output triggering of programmable timing pattern controller (TPC) Compare match/input capture signals from channels 0 to 3 can be used as TPC output triggers. Rev. 2.0, 03/01, page 306 of 822 Table 10.1 summarizes the ITU functions. Table 10.1 ITU Functions Item Clock sources General registers (output compare/input capture registers) Buffer registers Input/output pins Output pins Counter clearing function Channel 0 Channel 1 Channel 2 Channel 3 Channel 4 Internal clocks: , /2, /4, /8 External clocks: TCLKA, TCLKB, TCLKC, TCLKD, selectable independently GRA0, GRB0 GRA1, GRB1 GRA2, GRB2 GRA3, GRB3 GRA4, GRB4 -- TIOCA0, TIOCB0 -- GRA0/GRB0 compare match or input capture O O O O O O -- -- -- -- -- TIOCA1, TIOCB1 -- GRA1/GRB1 compare match or input capture O O O O O O -- -- -- -- -- TIOCA2, TIOCB2 -- GRA2/GRB2 compare match or input capture O O -- O O O -- -- O -- BRA3, BRB3 TIOCA3, TIOCB3 -- GRA3/GRB3 compare match or input capture O O O O O O O O -- O BRA4, BRB4 TIOCA4, TIOCB4 TOCXA4, TOCXB4 GRA4/GRB4 compare match or input capture O O O O O O O O -- O Compare match 0 output 1 Toggle Input capture function Synchronization PWM mode Reset-synchronized PWM mode Complementary PWM mode Phase counting mode Buffering DMAC activation GRA0 compare GRA1 compare GRA2 compare GRA3 compare -- match or input match or input match or input match or input capture capture capture capture Three sources * Compare match/input capture A0 * Compare match/input capture B0 * Overflow Three sources * Compare match/input capture A1 * Compare match/input capture B1 * Overflow Three sources * Compare match/input capture A2 * Compare match/input capture B2 * Overflow Three sources * Compare match/input capture A3 * Compare match/input capture B3 * Overflow Three sources * Compare match/input capture A4 * Compare match/input capture B4 * Overflow Interrupt sources Legend O: Available --: Not available Rev. 2.0, 03/01, page 307 of 822 10.1.2 Block Diagrams ITU Block Diagram (Overall): Figure 10.1 is a block diagram of the ITU. TCLKA to TCLKD , /2, /4, /8 TOCXA4, TOCXB4 TIOCA0 to TIOCA4 TIOCB0 to TIOCB4 Clock selector Control logic IMIA0 to IMIA4 IMIB0 to IMIB4 OVI0 to OVI4 TOER 16-bit timer channel 4 16-bit timer channel 3 16-bit timer channel 2 16-bit timer channel 1 16-bit timer channel 0 TOCR TSTR TSNC TMDR TFCR Internal data bus Bus interface Module data bus Legend TOER: TOCR: TSTR: TSNC: TMDR: TFCR: Timer output master enable register (8 bits) Timer output control register (8 bits) Timer start register (8 bits) Timer synchro register (8 bits) Timer mode register (8 bits) Timer function control register (8 bits) Figure 10.1 ITU Block Diagram (Overall) Rev. 2.0, 03/01, page 308 of 822 Block Diagram of Channels 0 and 1: ITU channels 0 and 1 are functionally identical. Both have the structure shown in figure 10.2. TCLKA to TCLKD , /2, /4, /8 Clock selector Control logic Comparator TIOCA0 TIOCB0 IMIA0 IMIB0 OVI0 TCNT TIOR TIER GRA GRB TCR Module data bus Legend TCNT: GRA, GRB: TCR: TIOR: TIER: TSR: Timer counter (16 bits) General registers A and B (input capture/output compare registers) (16 bits x 2) Timer control register (8 bits) Timer I/O control register (8 bits) Timer interrupt enable register (8 bits) Timer status register (8 bits) Figure 10.2 Block Diagram of Channels 0 and 1 (for Channel 0) Rev. 2.0, 03/01, page 309 of 822 TSR Block Diagram of Channel 2: Figure 10.3 is a block diagram of channel 2. This is the channel that provides only 0 output and 1 output. TCLKA to TCLKD , /2, /4, /8 Clock selector Control logic Comparator TIOCA2 TIOCB2 IMIA2 IMIB2 OVI2 TCNT2 TIOR2 TIER2 GRA2 GRB2 TCR2 Module data bus Legend Timer counter 2 (16 bits) TCNT2: GRA2, GRB2: General registers A2 and B2 (input capture/output compare registers) (16 bits x 2) Timer control register 2 (8 bits) TCR2: Timer I/O control register 2 (8 bits) TIOR2: Timer interrupt enable register 2 (8 bits) TIER2: Timer status register 2 (8 bits) TSR2: Figure 10.3 Block Diagram of Channel 2 Rev. 2.0, 03/01, page 310 of 822 TSR2 Block Diagrams of Channels 3 and 4: Figure 10.4 is a block diagram of channel 3. Figure 10.5 is a block diagram of channel 4. TCLKA to TCLKD , /2, /4, /8 Clock selector Control logic Comparator TIOCA3 TIOCB3 IMIA3 IMIB3 OVI3 TCNT3 TIOR3 TIER3 GRA3 GRB3 BRA3 BRB3 TCR3 Module data bus Legend Timer counter 3 (16 bits) TCNT3: GRA3, GRB3: General registers A3 and B3 (input capture/output compare registers) (16 bits x 2) BRA3, BRB3: Buffer registers A3 and B3 (input capture/output compare buffer registers) (16 bits x 2) Timer control register 3 (8 bits) TCR3: Timer I/O control register 3 (8 bits) TIOR3: Timer interrupt enable register 3 (8 bits) TIER3: Timer status register 3 (8 bits) TSR3: Figure 10.4 Block Diagram of Channel 3 Rev. 2.0, 03/01, page 311 of 822 TSR3 TCLKA to TCLKD , /2, /4, /8 Clock selector Control logic Comparator TOCXA4 TOCXB4 TIOCA4 TIOCB4 IMIA4 IMIB4 OVI4 TCNT4 TIOR4 TIER4 GRA4 GRB4 BRA4 BRB4 TCR4 Module data bus Legend Timer counter 4 (16 bits) TCNT4: GRA4, GRB4: General registers A4 and B4 (input capture/output compare registers) (16 bits x 2) BRA4, BRB4: Buffer registers A4 and B4 (input capture/output compare buffer registers) (16 bits x 2) Timer control register 4 (8 bits) TCR4: Timer I/O control register 4 (8 bits) TIOR4: Timer interrupt enable register 4 (8 bits) TIER4: Timer status register 4 (8 bits) TSR4: Figure 10.5 Block Diagram of Channel 4 Rev. 2.0, 03/01, page 312 of 822 TSR4 10.1.3 Pin Configuration Table 10.2 summarizes the ITU pins. Table 10.2 ITU Pins Channel Name Abbreviation TCLKA TCLKB TCLKC TCLKD TIOCA0 TIOCB0 TIOCA1 TIOCB1 TIOCA2 TIOCB2 TIOCA3 Input/ Output Input Input Input Input Input/ output Input/ output Input/ output Input/ output Input/ output Input/ output Input/ output Function External clock A input pin (phase-A input pin in phase counting mode) External clock B input pin (phase-B input pin in phase counting mode) External clock C input pin External clock D input pin GRA0 output compare or input capture pin PWM output pin in PWM mode GRB0 output compare or input capture pin GRA1 output compare or input capture pin PWM output pin in PWM mode GRB1 output compare or input capture pin GRA2 output compare or input capture pin PWM output pin in PWM mode GRB2 output compare or input capture pin GRA3 output compare or input capture pin PWM output pin in PWM mode, complementary PWM mode, or resetsynchronized PWM mode GRB3 output compare or input capture pin PWM output pin in complementary PWM mode or reset-synchronized PWM mode GRA4 output compare or input capture pin PWM output pin in PWM mode, complementary PWM mode, or resetsynchronized PWM mode GRB4 output compare or input capture pin PWM output pin in complementary PWM mode or reset-synchronized PWM mode PWM output pin in complementary PWM mode or reset-synchronized PWM mode PWM output pin in complementary PWM mode or reset-synchronized PWM mode Rev. 2.0, 03/01, page 313 of 822 Common Clock input A Clock input B Clock input C Clock input D 0 Input capture/output compare A0 Input capture/output compare B0 1 Input capture/output compare A1 Input capture/output compare B1 2 Input capture/output compare A2 Input capture/output compare B2 3 Input capture/output compare A3 Input capture/output compare B3 4 Input capture/output compare A4 TIOCB3 Input/ output Input/ output TIOCA4 Input capture/output compare B4 TIOCB4 Input/ output Output Output Output compare XA4 TOCXA4 Output compare XB4 TOCXB4 10.1.4 Register Configuration Table 10.3 summarizes the ITU registers. Table 10.3 ITU Registers Channel Common 1 Address* Name Timer start register Timer synchro register Timer mode register Timer function control register Timer output master enable register Timer output control register Timer control register 0 Timer I/O control register 0 Timer interrupt enable register 0 Timer status register 0 Timer counter 0 (high) Timer counter 0 (low) General register A0 (high) General register A0 (low) General register B0 (high) General register B0 (low) Timer control register 1 Timer I/O control register 1 Timer interrupt enable register 1 Timer status register 1 Timer counter 1 (high) Timer counter 1 (low) General register A1 (high) General register A1 (low) General register B1 (high) General register B1 (low) Abbreviation TSTR TSNC TMDR TFCR TOER TOCR TCR0 TIOR0 TIER0 TSR0 TCNT0H TCNT0L GRA0H GRA0L GRB0H GRB0L TCR1 TIOR1 TIER1 TSR1 TCNT1H TCNT1L GRA1H GRA1L GRB1H GRB1L R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/(W)* R/W R/W R/W R/W R/W R/W R/W R/W R/W R/(W)* R/W R/W R/W R/W R/W R/W 2 2 Initial Value H'E0 H'E0 H'80 H'C0 H'FF H'FF H'80 H'88 H'F8 H'F8 H'00 H'00 H'FF H'FF H'FF H'FF H'80 H'88 H'F8 H'F8 H'00 H'00 H'FF H'FF H'FF H'FF H'FF60 H'FF61 H'FF62 H'FF63 H'FF90 H'FF91 0 H'FF64 H'FF65 H'FF66 H'FF67 H'FF68 H'FF69 H'FF6A H'FF6B H'FF6C H'FF6D 1 H'FF6E H'FF6F H'FF70 H'FF71 H'FF72 H'FF73 H'FF74 H'FF75 H'FF76 H'FF77 Rev. 2.0, 03/01, page 314 of 822 Channel 2 Address* H'FF78 H'FF79 H'FF7A H'FF7B H'FF7C H'FF7D H'FF7E H'FF7F H'FF80 H'FF81 1 Name Timer control register 2 Timer I/O control register 2 Timer interrupt enable register 2 Timer status register 2 Timer counter 2 (high) Timer counter 2 (low) General register A2 (high) General register A2 (low) General register B2 (high) General register B2 (low) Timer control register 3 Timer I/O control register 3 Timer interrupt enable register 3 Timer status register 3 Timer counter 3 (high) Timer counter 3 (low) General register A3 (high) General register A3 (low) General register B3 (high) General register B3 (low) Buffer register A3 (high) Buffer register A3 (low) Buffer register B3 (high) Buffer register B3 (low) Abbreviation TCR2 TIOR2 TIER2 TSR2 TCNT2H TCNT2L GRA2H GRA2L GRB2H GRB2L TCR3 TIOR3 TIER3 TSR3 TCNT3H TCNT3L GRA3H GRA3L GRB3H GRB3L BRA3H BRA3L BRB3H BRB3L R/W R/W R/W R/W R/(W)* R/W R/W R/W R/W R/W R/W R/W R/W R/W R/(W)* R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W 2 2 Initial Value H'80 H'88 H'F8 H'F8 H'00 H'00 H'FF H'FF H'FF H'FF H'80 H'88 H'F8 H'F8 H'00 H'00 H'FF H'FF H'FF H'FF H'FF H'FF H'FF H'FF 3 H'FF82 H'FF83 H'FF84 H'FF85 H'FF86 H'FF87 H'FF88 H'FF89 H'FF8A H'FF8B H'FF8C H'FF8D H'FF8E H'FF8F Rev. 2.0, 03/01, page 315 of 822 Channel 4 Address* H'FF92 H'FF93 H'FF94 H'FF95 H'FF96 H'FF97 H'FF98 H'FF99 H'FF9A H'FF9B H'FF9C H'FF9D H'FF9E H'FF9F 1 Name Timer control register 4 Timer I/O control register 4 Timer interrupt enable register 4 Timer status register 4 Timer counter 4 (high) Timer counter 4 (low) General register A4 (high) General register A4 (low) General register B4 (high) General register B4 (low) Buffer register A4 (high) Buffer register A4 (low) Buffer register B4 (high) Buffer register B4 (low) Abbreviation TCR4 TIOR4 TIER4 TSR4 TCNT4H TCNT4L GRA4H GRA4L GRB4H GRB4L BRA4H BRA4L BRB4H BRB4L R/W R/W R/W R/W R/(W)* R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W 2 Initial Value H'80 H'88 H'F8 H'F8 H'00 H'00 H'FF H'FF H'FF H'FF H'FF H'FF H'FF H'FF Notes: 1. The lower 16 bits of the address are indicated. 2. Only 0 can be written, to clear flags. Rev. 2.0, 03/01, page 316 of 822 10.2 10.2.1 Register Descriptions Timer Start Register (TSTR) TSTR is an 8-bit readable/writable register that starts and stops the timer counter (TCNT) in channels 0 to 4. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- Reserved bits 5 -- 1 -- 4 STR4 0 R/W 3 STR3 0 R/W 2 STR2 0 R/W 1 STR1 0 R/W 0 STR0 0 R/W Counter start 4 to 0 These bits start and stop TCNT4 to TCNT0 TSTR is initialized to H'E0 by a reset and in standby mode. Bits 7 to 5--Reserved: Read-only bits, always read as 1. Bit 4--Counter Start 4 (STR4): Starts and stops timer counter 4 (TCNT4). Bit 4: STR4 0 1 Description TCNT4 is halted TCNT4 is counting (Initial value) Bit 3--Counter Start 3 (STR3): Starts and stops timer counter 3 (TCNT3). Bit 3: STR3 0 1 Description TCNT3 is halted TCNT3 is counting (Initial value) Bit 2--Counter Start 2 (STR2): Starts and stops timer counter 2 (TCNT2). Bit 2: STR2 0 1 Description TCNT2 is halted TCNT2 is counting (Initial value) Rev. 2.0, 03/01, page 317 of 822 Bit 1--Counter Start 1 (STR1): Starts and stops timer counter 1 (TCNT1). Bit 1: STR1 0 1 Description TCNT1 is halted TCNT1 is counting (Initial value) Bit 0--Counter Start 0 (STR0): Starts and stops timer counter 0 (TCNT0). Bit 0: STR0 0 1 Description TCNT0 is halted TCNT0 is counting (Initial value) 10.2.2 Timer Synchro Register (TSNC) TSNC is an 8-bit readable/writable register that selects whether channels 0 to 4 operate independently or synchronously. Channels are synchronized by setting the corresponding bits to 1. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- Reserved bits 5 -- 1 -- 4 SYNC4 0 R/W 3 SYNC3 0 R/W 2 SYNC2 0 R/W 1 SYNC1 0 R/W 0 SYNC0 0 R/W Timer sync 4 to 0 These bits synchronize channels 4 to 0 TSNC is initialized to H'E0 by a reset and in standby mode. Bits 7 to 5--Reserved: Read-only bits, always read as 1. Bit 4--Timer Sync 4 (SYNC4): Selects whether channel 4 operates independently or synchronously. Bit 4: SYNC4 0 1 Description Channel 4's timer counter (TCNT4) operates independently TCNT4 is preset and cleared independently of other channels Channel 4 operates synchronously TCNT4 can be synchronously preset and cleared (Initial value) Rev. 2.0, 03/01, page 318 of 822 Bit 3--Timer Sync 3 (SYNC3): Selects whether channel 3 operates independently or synchronously. Bit 3: SYNC3 0 1 Description Channel 3's timer counter (TCNT3) operates independently TCNT3 is preset and cleared independently of other channels Channel 3 operates synchronously TCNT3 can be synchronously preset and cleared (Initial value) Bit 2--Timer Sync 2 (SYNC2): Selects whether channel 2 operates independently or synchronously. Bit 2: SYNC2 0 1 Description Channel 2's timer counter (TCNT2) operates independently TCNT2 is preset and cleared independently of other channels Channel 2 operates synchronously TCNT2 can be synchronously preset and cleared (Initial value) Bit 1--Timer Sync 1 (SYNC1): Selects whether channel 1 operates independently or synchronously. Bit 1: SYNC1 0 1 Description Channel 1's timer counter (TCNT1) operates independently TCNT1 is preset and cleared independently of other channels Channel 1 operates synchronously TCNT1 can be synchronously preset and cleared (Initial value) Bit 0--Timer Sync 0 (SYNC0): Selects whether channel 0 operates independently or synchronously. Bit 0: SYNC0 0 1 Description Channel 0's timer counter (TCNT0) operates independently TCNT0 is preset and cleared independently of other channels Channel 0 operates synchronously TCNT0 can be synchronously preset and cleared (Initial value) Rev. 2.0, 03/01, page 319 of 822 10.2.3 Timer Mode Register (TMDR) TMDR is an 8-bit readable/writable register that selects PWM mode for channels 0 to 4. It also selects phase counting mode and the overflow flag (OVF) setting conditions for channel 2. Bit Initial value Read/Write 7 -- 1 -- 6 MDF 0 R/W 5 FDIR 0 R/W 4 PWM4 0 R/W 3 PWM3 0 R/W 2 PWM2 0 R/W 1 PWM1 0 R/W 0 PWM0 0 R/W PWM mode 4 to 0 These bits select PWM mode for channels 4 to 0 Flag direction Selects the setting condition for the overflow flag (OVF) in timer status register 2 (TSR2) Phase counting mode flag Selects phase counting mode for channel 2 Reserved bit TMDR is initialized to H'80 by a reset and in standby mode. Bit 7--Reserved: Read-only bit, always read as 1. Bit 6--Phase Counting Mode Flag (MDF): Selects whether channel 2 operates normally or in phase counting mode. Bit 6: MDF 0 1 Description Channel 2 operates normally Channel 2 operates in phase counting mode (Initial value) Rev. 2.0, 03/01, page 320 of 822 When MDF is set to 1 to select phase counting mode, TCNT2 operates as an up/down-counter and pins TCLKA and TCLKB become counter clock input pins. TCNT2 counts both rising and falling edges of TCLKA and TCLKB, and counts up or down as follows. Counting Direction TCLKA pin TCLKB pin Down-Counting Low High High Low Up-Counting High Low Low High In phase counting mode channel 2 operates as above regardless of the external clock edges selected by bits CKEG1 and CKEG0 and the clock source selected by bits TPSC2 to TPSC0 in TCR2. Phase counting mode takes precedence over these settings. The counter clearing condition selected by the CCLR1 and CCLR0 bits in TCR2 and the compare match/input capture settings and interrupt functions of TIOR2, TIER2, and TSR2 remain effective in phase counting mode. Bit 5--Flag Direction (FDIR): Designates the setting condition for the OVF flag in TSR2. The FDIR designation is valid in all modes in channel 2. Bit 5: FDIR 0 1 Description OVF is set to 1 in TSR2 when TCNT2 overflows or underflows OVF is set to 1 in TSR2 when TCNT2 overflows (Initial value) Bit 4--PWM Mode 4 (PWM4): Selects whether channel 4 operates normally or in PWM mode. Bit 4: PWM4 0 1 Description Channel 4 operates normally Channel 4 operates in PWM mode (Initial value) When bit PWM4 is set to 1 to select PWM mode, pin TIOCA4 becomes a PWM output pin. The output goes to 1 at compare match with GRA4, and to 0 at compare match with GRB4. If complementary PWM mode or reset-synchronized PWM mode is selected by bits CMD1 and CMD0 in TFCR, the CMD1 and CMD0 setting takes precedence and the PWM4 setting is ignored. Rev. 2.0, 03/01, page 321 of 822 Bit 3--PWM Mode 3 (PWM3): Selects whether channel 3 operates normally or in PWM mode. Bit 3: PWM3 0 1 Description Channel 3 operates normally Channel 3 operates in PWM mode (Initial value) When bit PWM3 is set to 1 to select PWM mode, pin TIOCA3 becomes a PWM output pin. The output goes to 1 at compare match with GRA3, and to 0 at compare match with GRB3. If complementary PWM mode or reset-synchronized PWM mode is selected by bits CMD1 and CMD0 in TFCR, the CMD1 and CMD0 setting takes precedence and the PWM3 setting is ignored. Bit 2--PWM Mode 2 (PWM2): Selects whether channel 2 operates normally or in PWM mode. Bit 2: PWM2 0 1 Description Channel 2 operates normally Channel 2 operates in PWM mode (Initial value) When bit PWM2 is set to 1 to select PWM mode, pin TIOCA2 becomes a PWM output pin. The output goes to 1 at compare match with GRA2, and to 0 at compare match with GRB2. Bit 1--PWM Mode 1 (PWM1): Selects whether channel 1 operates normally or in PWM mode. Bit 1: PWM1 0 1 Description Channel 1 operates normally Channel 1 operates in PWM mode (Initial value) When bit PWM1 is set to 1 to select PWM mode, pin TIOCA1 becomes a PWM output pin. The output goes to 1 at compare match with GRA1, and to 0 at compare match with GRB1. Bit 0--PWM Mode 0 (PWM0): Selects whether channel 0 operates normally or in PWM mode. Bit 0: PWM0 0 1 Description Channel 0 operates normally Channel 0 operates in PWM mode (Initial value) When bit PWM0 is set to 1 to select PWM mode, pin TIOCA0 becomes a PWM output pin. The output goes to 1 at compare match with GRA0, and to 0 at compare match with GRB0. Rev. 2.0, 03/01, page 322 of 822 10.2.4 Timer Function Control Register (TFCR) TFCR is an 8-bit readable/writable register that selects complementary PWM mode, resetsynchronized PWM mode, and buffering for channels 3 and 4. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 CMD1 0 R/W 4 CMD0 0 R/W 3 BFB4 0 R/W 2 BFA4 0 R/W 1 BFB3 0 R/W 0 BFA3 0 R/W Reserved bits Combination mode 1/0 These bits select complementary PWM mode or reset-synchronized PWM mode for channels 3 and 4 Buffer mode B4 and A4 These bits select buffering of general registers (GRB4 and GRA4) by buffer registers (BRB4 and BRA4) in channel 4 Buffer mode B3 and A3 These bits select buffering of general registers (GRB3 and GRA3) by buffer registers (BRB3 and BRA3) in channel 3 TFCR is initialized to H'C0 by a reset and in standby mode. Bits 7 and 6--Reserved: Read-only bits, always read as 1. Bits 5 and 4--Combination Mode 1 and 0 (CMD1, CMD0): These bits select whether channels 3 and 4 operate in normal mode, complementary PWM mode, or reset-synchronized PWM mode. Bit 5: CMD1 0 1 Bit 4: CMD0 0 1 0 1 Channels 3 and 4 operate together in complementary PWM mode Channels 3 and 4 operate together in reset-synchronized PWM mode Description Channels 3 and 4 operate normally (Initial value) Rev. 2.0, 03/01, page 323 of 822 Before selecting reset-synchronized PWM mode or complementary PWM mode, halt the timer counter or counters that will be used in these modes. When these bits select complementary PWM mode or reset-synchronized PWM mode, they take precedence over the setting of the PWM mode bits (PWM4 and PWM3) in TMDR. Settings of timer sync bits SYNC4 and SYNC3 in TSNC are valid in complementary PWM mode and resetsynchronized PWM mode, however. When complementary PWM mode is selected, channels 3 and 4 must not be synchronized (do not set bits SYNC3 and SYNC4 both to 1 in TSNC). Bit 3--Buffer Mode B4 (BFB4): Selects whether GRB4 operates normally in channel 4, or whether GRB4 is buffered by BRB4. Bit 3: BFB4 0 1 Description GRB4 operates normally GRB4 is buffered by BRB4 (Initial value) Bit 2--Buffer Mode A4 (BFA4): Selects whether GRA4 operates normally in channel 4, or whether GRA4 is buffered by BRA4. Bit 2: BFA4 0 1 Description GRA4 operates normally GRA4 is buffered by BRA4 (Initial value) Bit 1--Buffer Mode B3 (BFB3): Selects whether GRB3 operates normally in channel 3, or whether GRB3 is buffered by BRB3. Bit 1: BFB3 0 1 Description GRB3 operates normally GRB3 is buffered by BRB3 (Initial value) Bit 0--Buffer Mode A3 (BFA3): Selects whether GRA3 operates normally in channel 3, or whether GRA3 is buffered by BRA3. Bit 0: BFA3 0 1 Description GRA3 operates normally GRA3 is buffered by BRA3 (Initial value) Rev. 2.0, 03/01, page 324 of 822 10.2.5 Timer Output Master Enable Register (TOER) TOER is an 8-bit readable/writable register that enables or disables output settings for channels 3 and 4. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 EXB4 1 R/W 4 EXA4 1 R/W 3 EB3 1 R/W 2 EB4 1 R/W 1 EA4 1 R/W 0 EA3 1 R/W Reserved bits Master enable TOCXA4, TOCXB4 These bits enable or disable output settings for pins TOCXA4 and TOCXB4 Master enable TIOCA3, TIOCB3, TIOCA4, TIOCB4 These bits enable or disable output settings for pins TIOCA3, TIOCB3 , TIOCA4, and TIOCB4 TOER is initialized to H'FF by a reset and in standby mode. Bits 7 and 6--Reserved: Read-only bits, always read as 1. Bit 5--Master Enable TOCXB4 (EXB4): Enables or disables ITU output at pin TOCXB4. Bit 5: EXB4 0 Description TOCXB4 output is disabled regardless of TFCR settings (TOCXB4 operates as a generic input/output pin). If XTGD = 0, EXB4 is cleared to 0 when input capture A occurs in channel 1. 1 TOCXB4 is enabled for output according to TFCR settings (Initial value) Bit 4--Master Enable TOCXA4 (EXA4): Enables or disables ITU output at pin TOCXA4. Bit 4: EXA4 0 Description TOCXA4 output is disabled regardless of TFCR settings (TOCXA4 operates as a generic input/output pin). If XTGD = 0, EXA4 is cleared to 0 when input capture A occurs in channel 1. 1 TOCXA4 is enabled for output according to TFCR settings (Initial value) Rev. 2.0, 03/01, page 325 of 822 Bit 3--Master Enable TIOCB3 (EB3): Enables or disables ITU output at pin TIOCB3. Bit 3: EB3 0 Description TIOCB3 output is disabled regardless of TIOR3 and TFCR settings (TIOCB3 operates as a generic input/output pin). If XTGD = 0, EB3 is cleared to 0 when input capture A occurs in channel 1. 1 TIOCB3 is enabled for output according to TIOR3 and TFCR settings (Initial value) Bit 2--Master Enable TIOCB4 (EB4): Enables or disables ITU output at pin TIOCB4. Bit 2: EB4 0 Description TIOCB4 output is disabled regardless of TIOR4 and TFCR settings (TIOCB4 operates as a generic input/output pin). If XTGD = 0, EB4 is cleared to 0 when input capture A occurs in channel 1. 1 TIOCB4 is enabled for output according to TIOR4 and TFCR settings (Initial value) Bit 1--Master Enable TIOCA4 (EA4): Enables or disables ITU output at pin TIOCA4. Bit 1: EA4 0 Description TIOCA4 output is disabled regardless of TIOR4, TMDR, and TFCR settings (TIOCA4 operates as a generic input/output pin). If XTGD = 0, EA4 is cleared to 0 when input capture A occurs in channel 1. 1 TIOCA4 is enabled for output according to TIOR4, TMDR, and TFCR settings (Initial value) Bit 0--Master Enable TIOCA3 (EA3): Enables or disables ITU output at pin TIOCA3. Bit 0: EA3 0 Description TIOCA3 output is disabled regardless of TIOR3, TMDR, and TFCR settings (TIOCA3 operates as a generic input/output pin). If XTGD = 0, EA3 is cleared to 0 when input capture A occurs in channel 1. 1 TIOCA3 is enabled for output according to TIOR3, TMDR, and TFCR settings (Initial value) Rev. 2.0, 03/01, page 326 of 822 10.2.6 Timer Output Control Register (TOCR) TOCR is an 8-bit readable/writable register that selects externally triggered disabling of output in complementary PWM mode and reset-synchronized PWM mode, and inverts the output levels. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- Reserved bits 5 -- 1 -- 4 XTGD 1 R/W 3 -- 1 -- 2 -- 1 -- 1 OLS4 1 R/W 0 OLS3 1 R/W Output level select 3, 4 These bits select output levels in complementary PWM mode and resetsynchronized PWM mode Reserved bits External trigger disable Selects externally triggered disabling of output in complementary PWM mode and reset-synchronized PWM mode The settings of the XTGD, OLS4, and OLS3 bits are valid only in complementary PWM mode and reset-synchronized PWM mode. These settings do not affect other modes. TOCR is initialized to H'FF by a reset and in standby mode. Bits 7 to 5--Reserved: Read-only bits, always read as 1. Bit 4--External Trigger Disable (XTGD): Selects externally triggered disabling of ITU output in complementary PWM mode and reset-synchronized PWM mode. Bit 4: XTGD 0 Description Input capture A in channel 1 is used as an external trigger signal in complementary PWM mode and reset-synchronized PWM mode. When an external trigger occurs, bits 5 to 0 in TOER are cleared to 0, disabling ITU output. 1 External triggering is disabled (Initial value) Bits 3 and 2--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 327 of 822 Bit 1--Output Level Select 4 (OLS4): Selects output levels in complementary PWM mode and reset-synchronized PWM mode. Bit 1: OLS4 0 1 Description TIOCA3, TIOCA4, and TIOCB4 outputs are inverted TIOCA3, TIOCA4, and TIOCB4 outputs are not inverted (Initial value) Bit 0--Output Level Select 3 (OLS3): Selects output levels in complementary PWM mode and reset-synchronized PWM mode. Bit 0: OLS3 0 1 Description TIOCB3, TOCXA4, and TOCXB4 outputs are inverted TIOCB3, TOCXA4, and TOCXB4 outputs are not inverted (Initial value) 10.2.7 Timer Counters (TCNT) TCNT is a 16-bit counter. The ITU has five TCNTs, one for each channel. Channel 0 1 2 3 4 Abbreviation TCNT0 TCNT1 TCNT2 TCNT3 TCNT4 Phase counting mode: up/down-counter Other modes: up-counter Complementary PWM mode: up/down-counter Other modes: up-counter Function Up-counter Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Each TCNT is a 16-bit readable/writable register that counts pulse inputs from a clock source. The clock source is selected by bits TPSC2 to TPSC0 in TCR. TCNT0 and TCNT1 are up-counters. TCNT2 is an up/down-counter in phase counting mode and an up-counter in other modes. TCNT3 and TCNT4 are up/down-counters in complementary PWM mode and up-counters in other modes. Rev. 2.0, 03/01, page 328 of 822 TCNT can be cleared to H'0000 by compare match with GRA or GRB or by input capture to GRA or GRB (counter clearing function) in the same channel. When TCNT overflows (changes from H'FFFF to H'0000), the OVF flag is set to 1 in TSR of the corresponding channel. When TCNT underflows (changes from H'0000 to H'FFFF), the OVF flag is set to 1 in TSR of the corresponding channel. The TCNTs are linked to the CPU by an internal 16-bit bus and can be written or read by either word access or byte access. Each TCNT is initialized to H'0000 by a reset and in standby mode. 10.2.8 General Registers (GRA, GRB) The general registers are 16-bit registers. The ITU has 10 general registers, two in each channel. Channel 0 1 2 3 4 Abbreviation GRA0, GRB0 GRA1, GRB1 GRA2, GRB2 GRA3, GRB3 GRA4, GRB4 Output compare/input capture register; can be buffered by buffer registers BRA and BRB Function Output compare/input capture register Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 5 1 4 1 3 1 2 1 1 1 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W A general register is a 16-bit readable/writable register that can function as either an output compare register or an input capture register. The function is selected by settings in TIOR. When a general register is used as an output compare register, its value is constantly compared with the TCNT value. When the two values match (compare match), the IMFA or IMFB flag is set to 1 in TSR. Compare match output can be selected in TIOR. When a general register is used as an input capture register, rising edges, falling edges, or both edges of an external input capture signal are detected and the current TCNT value is stored in the general register. The corresponding IMFA or IMFB flag in TSR is set to 1 at the same time. The valid edge or edges of the input capture signal are selected in TIOR. Rev. 2.0, 03/01, page 329 of 822 TIOR settings are ignored in PWM mode, complementary PWM mode, and reset-synchronized PWM mode. General registers are linked to the CPU by an internal 16-bit bus and can be written or read by either word access or byte access. General registers are initialized to the output compare function (with no output signal) by a reset and in standby mode. The initial value is H'FFFF. 10.2.9 Buffer Registers (BRA, BRB) The buffer registers are 16-bit registers. The ITU has four buffer registers, two each in channels 3 and 4. Channel 3 4 Abbreviation BRA3, BRB3 BRA4, BRB4 Function Used for buffering * When the corresponding GRA or GRB functions as an output compare register, BRA or BRB can function as an output compare buffer register: the BRA or BRB value is automatically transferred to GRA or GRB at compare match When the corresponding GRA or GRB functions as an input capture register, BRA or BRB can function as an input capture buffer register: the GRA or GRB value is automatically transferred to BRA or BRB at input capture * Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 5 1 4 1 3 1 2 1 1 1 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W A buffer register is a 16-bit readable/writable register that is used when buffering is selected. Buffering can be selected independently by bits BFB4, BFA4, BFB3, and BFA3 in TFCR. The buffer register and general register operate as a pair. When the general register functions as an output compare register, the buffer register functions as an output compare buffer register. When the general register functions as an input capture register, the buffer register functions as an input capture buffer register. The buffer registers are linked to the CPU by an internal 16-bit bus and can be written or read by either word or byte access. Buffer registers are initialized to H'FFFF by a reset and in standby mode. Rev. 2.0, 03/01, page 330 of 822 10.2.10 Timer Control Registers (TCR) TCR is an 8-bit register. The ITU has five TCRs, one in each channel. Channel 0 1 2 3 4 Abbreviation TCR0 TCR1 TCR2 TCR3 TCR4 Function TCR controls the timer counter. The TCRs in all channels are functionally identical. When phase counting mode is selected in channel 2, the settings of bits CKEG1 and CKEG0 and TPSC2 to TPSC0 in TCR2 are ignored. Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 CKEG1 0 R/W 3 CKEG0 0 R/W 2 TPSC2 0 R/W 1 TPSC1 0 R/W 0 TPSC0 0 R/W Timer prescaler 2 to 0 These bits select the counter clock Clock edge 1/0 These bits select external clock edges Counter clear 1/0 These bits select the counter clear source Reserved bit Each TCR is an 8-bit readable/writable register that selects the timer counter clock source, selects the edge or edges of external clock sources, and selects how the counter is cleared. TCR is initialized to H'80 by a reset and in standby mode. Bit 7--Reserved: Read-only bit, always read as 1. Rev. 2.0, 03/01, page 331 of 822 Bits 6 and 5--Counter Clear 1/0 (CCLR1, CCLR0): These bits select how TCNT is cleared. Bit 6: CCLR1 0 Bit 5: CCLR0 0 1 1 0 1 Description TCNT is not cleared (Initial value) TCNT is cleared by GRA compare match or input 1 capture* TCNT is cleared by GRB compare match or input 1 capture* Synchronous clear: TCNT is cleared in synchronization 2 with other synchronized timers* Notes: 1. TCNT is cleared by compare match when the general register functions as an output compare register, and by input capture when the general register functions as an input capture register. 2. Selected in TSNC. Bits 4 and 3--Clock Edge 1/0 (CKEG1, CKEG0): These bits select external clock input edges when an external clock source is used. Bit 4: CKEG1 0 1 Bit 3: CKEG0 0 1 -- Description Count rising edges Count falling edges Count both edges (Initial value) When channel 2 is set to phase counting mode, bits CKEG1 and CKEG0 in TCR2 are ignored. Phase counting takes precedence. Bits 2 to 0--Timer Prescaler 2 to 0 (TPSC2 to TPSC0): These bits select the counter clock source. Bit 2: TPSC2 0 Bit 1: TPSC1 0 1 1 0 1 Bit 0: TPSC0 0 1 0 1 0 1 0 1 Description Internal clock: Internal clock: /2 Internal clock: /4 Internal clock: /8 External clock A: TCLKA input External clock B: TCLKB input External clock C: TCLKC input External clock D: TCLKD input (Initial value) Rev. 2.0, 03/01, page 332 of 822 When bit TPSC2 is cleared to 0 an internal clock source is selected, and the timer counts only falling edges. When bit TPSC2 is set to 1 an external clock source is selected, and the timer counts the edge or edges selected by bits CKEG1 and CKEG0. When channel 2 is set to phase counting mode (MDF = 1 in TMDR), the settings of bits TPSC2 to TPSC0 in TCR2 are ignored. Phase counting takes precedence. 10.2.11 Timer I/O Control Register (TIOR) TIOR is an 8-bit register. The ITU has five TIORs, one in each channel. Channel 0 1 2 3 4 Abbreviation TIOR0 TIOR1 TIOR2 TIOR3 TIOR4 Function TIOR controls the general registers. Some functions differ in PWM mode. TIOR3 and TIOR4 settings are ignored when complementary PWM mode or reset-synchronized PWM mode is selected in channels 3 and 4. Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- 2 IOA2 0 R/W 1 IOA1 0 R/W 0 IOA0 0 R/W I/O control A2 to A0 These bits select GRA functions Reserved bit I/O control B2 to B0 These bits select GRB functions Reserved bit Each TIOR is an 8-bit readable/writable register that selects the output compare or input capture function for GRA and GRB, and specifies the functions of the TIOCA and TIOCB pins. If the output compare function is selected, TIOR also selects the type of output. If input capture is selected, TIOR also selects the edge or edges of the input capture signal. TIOR is initialized to H'88 by a reset and in standby mode. Bit 7--Reserved: Read-only bit, always read as 1. Rev. 2.0, 03/01, page 333 of 822 Bits 6 to 4--I/O Control B2 to B0 (IOB2 to IOB0): These bits select the GRB function. Bit 6: IOB2 0 Bit 5: IOB1 0 1 Bit 4: IOB0 0 1 0 1 1 0 1 0 1 0 1 Notes: 1. After a reset, the output is 0 until the first compare match. 2. Channel 2 output cannot be toggled by compare match. This setting selects 1 output instead. GRB is an input capture register Description GRB is an output compare register No output at compare match (Initial value) 0 output at GRB compare match* 1 output at GRB compare match* 1 1 Output toggles at GRB compare match 1, 2 (1 output in channel 2)* * GRB captures rising edge of input GRB captures falling edge of input GRB captures both edges of input Bit 3--Reserved: Read-only bit, always read as 1. Bits 2 to 0--I/O Control A2 to A0 (IOA2 to IOA0): These bits select the GRA function. Bit 2: IOA2 0 Bit 1: IOA1 0 1 Bit 0: IOA0 0 1 0 1 1 0 1 0 1 0 1 Notes: 1. After a reset, the output is 0 until the first compare match. 2. Channel 2 output cannot be toggled by compare match. This setting selects 1 output instead. GRA is an input capture register Description GRA is an output compare register No output at compare match (Initial value) 0 output at GRA compare match* 1 output at GRA compare match* 1 1 Output toggles at GRA compare match 1, 2 (1 output in channel 2)* * GRA captures rising edge of input GRA captures falling edge of input GRA captures both edges of input Rev. 2.0, 03/01, page 334 of 822 10.2.12 Timer Status Register (TSR) TSR is an 8-bit register. The ITU has five TSRs, one in each channel. Channel 0 1 2 3 4 Abbreviation TSR0 TSR1 TSR2 TSR3 TSR4 Function Indicates input capture, compare match, and overflow status Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- Reserved bits 4 -- 1 -- 3 -- 1 -- 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* 0 IMFA 0 R/(W)* Overflow flag Status flag indicating overflow or underflow Input capture/compare match flag B Status flag indicating GRB compare match or input capture Input capture/compare match flag A Status flag indicating GRA compare match or input capture Note: * Only 0 can be written, to clear the flag. Each TSR is an 8-bit readable/writable register containing flags that indicate TCNT overflow or underflow and GRA or GRB compare match or input capture. These flags are interrupt sources and generate CPU interrupts if enabled by corresponding bits in TIER. TSR is initialized to H'F8 by a reset and in standby mode. Bits 7 to 3--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 335 of 822 Bit 2--Overflow Flag (OVF): This status flag indicates TCNT overflow or underflow. Bit 2: OVF 0 1 Description [Clearing condition] Read OVF when OVF = 1, then write 0 in OVF [Setting condition] TCNT overflowed from H'FFFF to H'0000, or underflowed from H'0000 to H'FFFF* Notes: * TCNT underflow occurs when TCNT operates as an up/down-counter. Underflow occurs only under the following conditions: 1. Channel 2 operates in phase counting mode (MDF = 1 in TMDR) 2. Channels 3 and 4 operate in complementary PWM mode (CMD1 = 1 and CMD0 = 0 in TFCR) (Initial value) Bit 1--Input Capture/Compare Match Flag B (IMFB): This status flag indicates GRB compare match or input capture events. Bit 1: IMFB 0 1 Description [Clearing condition] Read IMFB when IMFB = 1, then write 0 in IMFB [Setting conditions] TCNT = GRB when GRB functions as an output compare register. TCNT value is transferred to GRB by an input capture signal, when GRB functions as an input capture register. (Initial value) Bit 0--Input Capture/Compare Match Flag A (IMFA): This status flag indicates GRA compare match or input capture events. Bit 0: IMFA 0 Description [Clearing condition] Read IMFA when IMFA = 1, then write 0 in IMFA. DMAC activated by IMIA interrupt (channels 0 to 3 only). 1 [Setting conditions] TCNT = GRA when GRA functions as an output compare register. TCNT value is transferred to GRA by an input capture signal, when GRA functions as an input capture register. (Initial value) Rev. 2.0, 03/01, page 336 of 822 10.2.13 Timer Interrupt Enable Register (TIER) TIER is an 8-bit register. The ITU has five TIERs, one in each channel. Channel 0 1 2 3 4 Abbreviation TIER0 TIER1 TIER2 TIER3 TIER4 Function Enables or disables interrupt requests. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- Reserved bits 4 -- 1 -- 3 -- 1 -- 2 OVIE 0 R/W 1 IMIEB 0 R/W 0 IMIEA 0 R/W Overflow interrupt enable Enables or disables OVF interrupts Input capture/compare match interrupt enable B Enables or disables IMFB interrupts Input capture/compare match interrupt enable A Enables or disables IMFA interrupts Each TIER is an 8-bit readable/writable register that enables and disables overflow interrupt requests and general register input capture and compare match interrupt requests. TIER is initialized to H'F8 by a reset and in standby mode. Bits 7 to 3--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 337 of 822 Bit 2--Overflow Interrupt Enable (OVIE): Enables or disables the interrupt requested by the OVF flag in TSR when OVF is set to 1. Bit 2: OVIE 0 1 Description OVI interrupt requested by OVF is disabled OVI interrupt requested by OVF is enabled (Initial value) Bit 1--Input Capture/Compare Match Interrupt Enable B (IMIEB): Enables or disables the interrupt requested by the IMFB flag in TSR when IMFB is set to 1. Bit 1: IMIEB 0 1 Description IMIB interrupt requested by IMFB is disabled IMIB interrupt requested by IMFB is enabled (Initial value) Bit 0--Input Capture/Compare Match Interrupt Enable A (IMIEA): Enables or disables the interrupt requested by the IMFA flag in TSR when IMFA is set to 1. Bit 0: IMIEA 0 1 Description IMIA interrupt requested by IMFA is disabled IMIA interrupt requested by IMFA is enabled (Initial value) Rev. 2.0, 03/01, page 338 of 822 10.3 10.3.1 CPU Interface 16-Bit Accessible Registers The timer counters (TCNTs), general registers A and B (GRAs and GRBs), and buffer registers A and B (BRAs and BRBs) are 16-bit registers, and are linked to the CPU by an internal 16-bit data bus. These registers can be written or read a word at a time, or a byte at a time. Figures 10.6 and 10.7 show examples of word access to a timer counter (TCNT). Figures 10.8, 10.9, 10.10, and 10.11 show examples of byte access to TCNTH and TCNTL. On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.6 Access to Timer Counter (CPU Writes to TCNT, Word) On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.7 Access to Timer Counter (CPU Reads TCNT, Word) Rev. 2.0, 03/01, page 339 of 822 On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.8 Access to Timer Counter (CPU Writes to TCNT, Upper Byte) On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.9 Access to Timer Counter (CPU Writes to TCNT, Lower Byte) On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.10 Access to Timer Counter (CPU Reads TCNT, Upper Byte) Rev. 2.0, 03/01, page 340 of 822 On-chip data bus H CPU L Bus interface H L Module data bus TCNTH TCNTL Figure 10.11 Access to Timer Counter (CPU Reads TCNT, Lower Byte) 10.3.2 8-Bit Accessible Registers The registers other than the timer counters (TCNTS), general registers A and B (GRAs and GRBs), and buffer registers A and B (BRAs and BRBs) are 8-bit registers. These registers are linked to the CPU by an internal 8-bit data bus. Figures 10.12 and 10.13 show examples of byte read and write access to a TCR. If a word-size data transfer instruction is executed, two byte transfers are performed. On-chip data bus H CPU L Bus interface H L Module data bus TCR Figure 10.12 Access to Timer Counter (CPU Writes to TCR) Rev. 2.0, 03/01, page 341 of 822 On-chip data bus H CPU L Bus interface H L Module data bus TCR Figure 10.13 Access to Timer Counter (CPU Reads TCR) Rev. 2.0, 03/01, page 342 of 822 10.4 10.4.1 Operation Overview A summary of operations in the various modes is given below. Normal Operation: Each channel has a timer counter and general registers. The timer counter counts up, and can operate as a free-running counter, periodic counter, or external event counter. General registers A and B can be used for input capture or output compare. Synchronous Operation: The timer counters in designated channels are preset synchronously. Data written to the timer counter in any one of these channels is simultaneously written to the timer counters in the other channels as well. The timer counters can also be cleared synchronously if so designated by the CCLR1 and CCLR0 bits in the TCRs. PWM Mode: A PWM waveform is output from the TIOCA pin. The output goes to 1 at compare match A and to 0 at compare match B. The duty cycle can be varied from 0% to 100% depending on the settings of GRA and GRB. When a channel is set to PWM mode, its GRA and GRB automatically become output compare registers. Reset-Synchronized PWM Mode: Channels 3 and 4 are paired for three-phase PWM output with complementary waveforms. (The three phases are related by having a common transition point.) When reset-synchronized PWM mode is selected GRA3, GRB3, GRA4, and GRB4 automatically function as output compare registers, TIOCA3, TIOCB3, TIOCA4, TOCXA4, TIOCB4, and TOCXB4 function as PWM output pins, and TCNT3 operates as an up-counter. TCNT4 operates independently, and is not compared with GRA4 or GRB4. Complementary PWM Mode: Channels 3 and 4 are paired for three-phase PWM output with non-overlapping complementary waveforms. When complementary PWM mode is selected GRA3, GRB3, GRA4, and GRB4 automatically function as output compare registers, and TIOCA3, TIOCB3, TIOCA4, TOCXA4, TIOCB4, and TOCXB4 function as PWM output pins. TCNT3 and TCNT4 operate as up/down-counters. Phase Counting Mode: The phase relationship between two clock signals input at TCLKA and TCLKB is detected and TCNT2 counts up or down accordingly. When phase counting mode is selected TCLKA and TCLKB become clock input pins and TCNT2 operates as an up/downcounter. Rev. 2.0, 03/01, page 343 of 822 Buffering * If the general register is an output compare register When compare match occurs the buffer register value is transferred to the general register. * If the general register is an input capture register When input capture occurs the TCNT value is transferred to the general register, and the previous general register value is transferred to the buffer register. * Complementary PWM mode The buffer register value is transferred to the general register when TCNT3 and TCNT4 change counting direction. * Reset-synchronized PWM mode The buffer register value is transferred to the general register at GRA3 compare match. 10.4.2 Basic Functions Counter Operation: When one of bits STR0 to STR4 is set to 1 in the timer start register (TSTR), the timer counter (TCNT) in the corresponding channel starts counting. The counting can be freerunning or periodic. * Sample setup procedure for counter Figure 10.14 shows a sample procedure for setting up a counter. Rev. 2.0, 03/01, page 344 of 822 Counter setup Select counter clock 1 Type of counting? Yes No Free-running counting Periodic counting Select counter clear source 2 Select output compare register function 3 Set period 4 Start counter Periodic counter 5 Start counter Free-running counter 5 1. Set bits TPSC2 to TPSC0 in TCR to select the counter clock source. If an external clock source is selected, set bits CKEG1 and CKEG0 in TCR to select the desired edge(s) of the external clock signal. 2. For periodic counting, set CCLR1 and CCLR0 in TCR to have TCNT cleared at GRA compare match or GRB compare match. 3. Set TIOR to select the output compare function of GRA or GRB, whichever was selected in step 2. 4. Write the count period in GRA or GRB, whichever was selected in step 2. 5. Set the STR bit to 1 in TSTR to start the timer counter. Figure 10.14 Counter Setup Procedure (Example) Rev. 2.0, 03/01, page 345 of 822 * Free-running and periodic counter operation A reset leaves the counters (TCNTs) in ITU channels 0 to 4 all set as free-running counters. A free-running counter starts counting up when the corresponding bit in TSTR is set to 1. When the count overflows from H'FFFF to H'0000, the OVF flag is set to 1 in TSR. If the corresponding OVIE bit is set to 1 in TIER, a CPU interrupt is requested. After the overflow, the counter continues counting up from H'0000. Figure 10.15 illustrates free-running counting. TCNT value H'FFFF H'0000 STR0 to STR4 bit OVF Time Figure 10.15 Free-Running Counter Operation When a channel is set to have its counter cleared by compare match, in that channel TCNT operates as a periodic counter. Select the output compare function of GRA or GRB, set bit CCLR1 or CCLR0 in TCR to have the counter cleared by compare match, and set the count period in GRA or GRB. After these settings, the counter starts counting up as a periodic counter when the corresponding bit is set to 1 in TSTR. When the count matches GRA or GRB, the IMFA or IMFB flag is set to 1 in TSR and the counter is cleared to H'0000. If the corresponding IMIEA or IMIEB bit is set to 1 in TIER, a CPU interrupt is requested at this time. After the compare match, TCNT continues counting up from H'0000. Figure 10.16 illustrates periodic counting. Rev. 2.0, 03/01, page 346 of 822 TCNT value GR Counter cleared by general register compare match H'0000 STR bit IMF Time Figure 10.16 Periodic Counter Operation * TCNT count timing Internal clock source Bits TPSC2 to TPSC0 in TCR select the system clock () or one of three internal clock sources obtained by prescaling the system clock (/2, /4, /8). Figure 10.17 shows the timing. Internal clock TCNT input TCNT N-1 N N+1 Figure 10.17 Count Timing for Internal Clock Sources External clock source Bits TPSC2 to TPSC0 in TCR select an external clock input pin (TCLKA to TCLKD), and its valid edge or edges are selected by bits CKEG1 and CKEG0. The rising edge, falling edge, or both edges can be selected. The pulse width of the external clock signal must be at least 1.5 system clocks when a single edge is selected, and at least 2.5 system clocks when both edges are selected. Shorter pulses will not be counted correctly. Figure 10.18 shows the timing when both edges are detected. Rev. 2.0, 03/01, page 347 of 822  External clock input TCNT input TCNT N-1 N N+1 Figure 10.18 Count Timing for External Clock Sources (when Both Edges are Detected) Waveform Output by Compare Match: In ITU channels 0, 1, 3, and 4, compare match A or B can cause the output at the TIOCA or TIOCB pin to go to 0, go to 1, or toggle. In channel 2 the output can only go to 0 or go to 1. * Sample setup procedure for waveform output by compare match Figure 10.19 shows a sample procedure for setting up waveform output by compare match. Output setup Select waveform output mode 1 1. Select the compare match output mode (0, 1, or toggle) in TIOR. When a waveform output mode is selected, the pin switches from its generic input/ output function to the output compare function (TIOCA or TIOCB). An output compare pin outputs 0 until the first compare match occurs. Set output timing 2 2. Set a value in GRA or GRB to designate the compare match timing. Start counter 3 3. Set the STR bit to 1 in TSTR to start the timer counter. Waveform output Figure 10.19 Setup Procedure for Waveform Output by Compare Match (Example) * Examples of waveform output Figure 10.20 shows examples of 0 and 1 output. TCNT operates as a free-running counter, 0 output is selected for compare match A, and 1 output is selected for compare match B. When the pin is already at the selected output level, the pin level does not change. Rev. 2.0, 03/01, page 348 of 822 TCNT value H'FFFF GRB GRA H'0000 TIOCB Time No change No change 1 output TIOCA No change No change 0 output Figure 10.20 0 and 1 Output (Examples) Figure 10.21 shows examples of toggle output. TCNT operates as a periodic counter, cleared by compare match B. Toggle output is selected for both compare match A and B. TCNT value GRB Counter cleared by compare match with GRB GRA H'0000 TIOCB Time Toggle output Toggle output TIOCA Figure 10.21 Toggle Output (Example) Rev. 2.0, 03/01, page 349 of 822 * Output compare timing The compare match signal is generated in the last state in which TCNT and the general register match (when TCNT changes from the matching value to the next value). When the compare match signal is generated, the output value selected in TIOR is output at the output compare pin (TIOCA or TIOCB). When TCNT matches a general register, the compare match signal is not generated until the next counter clock pulse. Figure 10.22 shows the output compare timing. TCNT input clock TCNT N N+1 GR Compare match signal TIOCA, TIOCB N Figure 10.22 Output Compare Timing Input Capture Function: The TCNT value can be captured into a general register when a transition occurs at an input capture/output compare pin (TIOCA or TIOCB). Capture can take place on the rising edge, falling edge, or both edges. The input capture function can be used to measure pulse width or period. * Sample setup procedure for input capture Figure 10.23 shows a sample procedure for setting up input capture. Rev. 2.0, 03/01, page 350 of 822 Input selection Select input-capture input 1 1. Set TIOR to select the input capture function of a general register and the rising edge, falling edge, or both edges of the input capture signal. Clear the port data direction bit to 0 before making these TIOR settings. Start counter 2 2. Set the STR bit to 1 in TSTR to start the timer counter. Input capture Figure 10.23 Setup Procedure for Input Capture (Example) * Examples of input capture Figure 10.24 illustrates input capture when the falling edge of TIOCB and both edges of TIOCA are selected as capture edges. TCNT is cleared by input capture into GRB. TCNT value H'0180 H'0160 H'0005 H'0000 TIOCB Counter cleared by TIOCB input (falling edge) Time TIOCA GRA H'0005 H'0160 GRB H'0180 Figure 10.24 Input Capture (Example) Rev. 2.0, 03/01, page 351 of 822 * Input capture signal timing Input capture on the rising edge, falling edge, or both edges can be selected by settings in TIOR. Figure 10.25 shows the timing when the rising edge is selected. The pulse width of the input capture signal must be at least 1.5 system clocks for single-edge capture, and 2.5 system clocks for capture of both edges. Input-capture input Internal input capture signal TCNT N GRA, GRB N Figure 10.25 Input Capture Signal Timing Rev. 2.0, 03/01, page 352 of 822 10.4.3 Synchronization The synchronization function enables two or more timer counters to be synchronized by writing the same data to them simultaneously (synchronous preset). With appropriate TCR settings, two or more timer counters can also be cleared simultaneously (synchronous clear). Synchronization enables additional general registers to be associated with a single time base. Synchronization can be selected for all channels (0 to 4). Sample Setup Procedure for Synchronization: Figure 10.26 shows a sample procedure for setting up synchronization. Setup for synchronization Select synchronization 1 Synchronous preset Synchronous clear Write to TCNT 2 Clearing synchronized to this channel? Yes Select counter clear source No 3 Select counter clear source 4 Start counter 5 Start counter 5 Synchronous preset Counter clear Synchronous clear 1. Set the SYNC bits to 1 in TSNC for the channels to be synchronized. 2. When a value is written in TCNT in one of the synchronized channels, the same value is simultaneously written in TCNT in the other channels (synchronized preset). 3. Set the CCLR1 or CCLR0 bit in TCR to have the counter cleared by compare match or input capture. 4. Set the CCLR1 and CCLR0 bits in TCR to have the counter cleared synchronously. 5. Set the STR bits in TSTR to 1 to start the synchronized counters. Figure 10.26 Setup Procedure for Synchronization (Example) Rev. 2.0, 03/01, page 353 of 822 Example of Synchronization: Figure 10.27 shows an example of synchronization. Channels 0, 1, and 2 are synchronized, and are set to operate in PWM mode. Channel 0 is set for counter clearing by compare match with GRB0. Channels 1 and 2 are set for synchronous counter clearing. The timer counters in channels 0, 1, and 2 are synchronously preset, and are synchronously cleared by compare match with GRB0. A three-phase PWM waveform is output from pins TIOCA0, TIOCA1, and TIOCA2. For further information on PWM mode, see section 10.4.4, PWM Mode. Value of TCNT0 to TCNT2 Cleared by compare match with GRB0 GRB0 GRB1 GRA0 GRB2 GRA1 GRA2 H'0000 TIOCA0 Time TIOCA1 TIOCA2 Figure 10.27 Synchronization (Example) Rev. 2.0, 03/01, page 354 of 822 10.4.4 PWM Mode In PWM mode GRA and GRB are paired and a PWM waveform is output from the TIOCA pin. GRA specifies the time at which the PWM output changes to 1. GRB specifies the time at which the PWM output changes to 0. If either GRA or GRB is selected as the counter clear source, a PWM waveform with a duty cycle from 0% to 100% is output at the TIOCA pin. PWM mode can be selected in all channels (0 to 4). Table 10.4 summarizes the PWM output pins and corresponding registers. If the same value is set in GRA and GRB, the output does not change when compare match occurs. Table 10.4 Channel 0 1 2 3 4 PWM Output Pins and Registers Output Pin TIOCA0 TIOCA1 TIOCA2 TIOCA3 TIOCA4 1 Output GRA0 GRA1 GRA2 GRA3 GRA4 0 Output GRB0 GRB1 GRB2 GRB3 GRB4 Rev. 2.0, 03/01, page 355 of 822 Sample Setup Procedure for PWM Mode: Figure 10.28 shows a sample procedure for setting up PWM mode. PWM mode 1. Set bits TPSC2 to TPSC0 in TCR to select the counter clock source. If an external clock source is selected, set bits CKEG1 and CKEG0 in TCR to select the desired edge(s) of the external clock signal. 1 2. Set bits CCLR1 and CCLR0 in TCR to select the counter clear source. 3. Set the time at which the PWM waveform should go to 1 in GRA. 4. Set the time at which the PWM waveform should go to 0 in GRB. Select counter clock Select counter clear source 2 Set GRA 3 Set GRB 4 Select PWM mode 5 5. Set the PWM bit in TMDR to select PWM mode. When PWM mode is selected, regardless of the TIOR contents, GRA and GRB become output compare registers specifying the times at which the PWM output goes to 1 and 0. The TIOCA pin automatically becomes the PWM output pin. The TIOCB pin conforms to the settings of bits IOB1 and IOB0 in TIOR. If TIOCB output is not desired, clear both IOB1 and IOB0 to 0. 6. Set the STR bit to 1 in TSTR to start the timer counter. Start counter 6 PWM mode Figure 10.28 Setup Procedure for PWM Mode (Example) Rev. 2.0, 03/01, page 356 of 822 Examples of PWM Mode: Figure 10.29 shows examples of operation in PWM mode. In PWM mode TIOCA becomes an output pin. The output goes to 1 at compare match with GRA, and to 0 at compare match with GRB. In the examples shown, TCNT is cleared by compare match with GRA or GRB. Synchronized operation and free-running counting are also possible. TCNT value Counter cleared by compare match with GRA GRA GRB H'0000 Time TIOCA a. Counter cleared by GRA TCNT value Counter cleared by compare match with GRB GRB GRA H'0000 Time TIOCA b. Counter cleared by GRB Figure 10.29 PWM Mode (Example 1) Rev. 2.0, 03/01, page 357 of 822 Figure 10.30 shows examples of the output of PWM waveforms with duty cycles of 0% and 100%. If the counter is cleared by compare match with GRB, and GRA is set to a higher value than GRB, the duty cycle is 0%. If the counter is cleared by compare match with GRA, and GRB is set to a higher value than GRA, the duty cycle is 100%. TCNT value GRB Counter cleared by compare match with GRB GRA H'0000 Time TIOCA Write to GRA a. 0% duty cycle TCNT value GRA Write to GRA Counter cleared by compare match with GRA GRB H'0000 Time TIOCA Write to GRB Write to GRB b. 100% duty cycle Figure 10.30 PWM Mode (Example 2) Rev. 2.0, 03/01, page 358 of 822 10.4.5 Reset-Synchronized PWM Mode In reset-synchronized PWM mode channels 3 and 4 are combined to produce three pairs of complementary PWM waveforms, all having one waveform transition point in common. When reset-synchronized PWM mode is selected TIOCA3, TIOCB3, TIOCA4, TOCXA4, TIOCB4, and TOCXB4 automatically become PWM output pins, and TCNT3 functions as an up-counter. Table 10.5 lists the PWM output pins. Table 10.6 summarizes the register settings. Table 10.5 Channel 3 4 Output Pins in Reset-Synchronized PWM Mode Output Pin TIOCA3 TIOCB3 TIOCA4 TOCXA4 TIOCB4 TOCXB4 Description PWM output 1 PWM output 1' (complementary waveform to PWM output 1) PWM output 2 PWM output 2' (complementary waveform to PWM output 2) PWM output 3 PWM output 3' (complementary waveform to PWM output 3) Table 10.6 Register TCNT3 TCNT4 GRA3 GRB3 GRA4 GRB4 Register Settings in Reset-Synchronized PWM Mode Setting Initially set to H'0000 Not used (operates independently) Specifies the count period of TCNT3 Specifies a transition point of PWM waveforms output from TIOCA3 and TIOCB3 Specifies a transition point of PWM waveforms output from TIOCA4 and TOCXA4 Specifies a transition point of PWM waveforms output from TIOCB4 and TOCXB4 Rev. 2.0, 03/01, page 359 of 822 Sample Setup Procedure for Reset-Synchronized PWM Mode: Figure 10.31 shows a sample procedure for setting up reset-synchronized PWM mode. Reset-synchronized PWM mode 1. Clear the STR3 bit in TSTR to 0 to halt TCNT3. Reset-synchronized PWM mode must be set up while TCNT3 is halted. 2. Set bits TPSC2 to TPSC0 in TCR to select the counter clock source for channel 3. If an external clock source is selected, select the external clock edge(s) with bits CKEG1 and CKEG0 in TCR. 3. Set bits CCLR1 and CCLR0 in TCR3 to select GRA3 compare match as the counter clear source. Stop counter 1 Select counter clock 2 Select counter clear source 3 Select reset-synchronized PWM mode 4 4. Set bits CMD1 and CMD0 in TFCR to select reset-synchronized PWM mode. TIOCA3, TIOCB3, TIOCA4, TIOCB4, TOCXA4, and TOCXB4 automatically become PWM output pins. 5. Preset TCNT3 to H'0000. TCNT4 need not be preset. 6. GRA3 is the waveform period register. Set the waveform period value in GRA3. Set transition times of the PWM output waveforms in GRB3, GRA4, and GRB4. Set times within the compare match range of TCNT3. X GRA3 (X: setting value) 7. Set the STR3 bit in TSTR to 1 to start TCNT3. Set TCNT 5 Set general registers 6 Start counter 7 Reset-synchronized PWM mode Figure 10.31 Setup Procedure for Reset-Synchronized PWM Mode (Example) Rev. 2.0, 03/01, page 360 of 822 Example of Reset-Synchronized PWM Mode: Figure 10.32 shows an example of operation in reset-synchronized PWM mode. TCNT3 operates as an up-counter in this mode. TCNT4 operates independently, detached from GRA4 and GRB4. When TCNT3 matches GRA3, TCNT3 is cleared and resumes counting from H'0000. The PWM outputs toggle at compare match of TCNT3 with GRB3, GRA4, and GRB4 respectively, and all toggle when the counter is cleared. TCNT3 value Counter cleared at compare match with GRA3 GRA3 GRB3 GRA4 GRB4 H'0000 Time TIOCA3 TIOCB3 TIOCA4 TOCXA4 TIOCB4 TOCXB4 Figure 10.32 Operation in Reset-Synchronized PWM Mode (Example) (when OLS3 = OLS4 = 1) For the settings and operation when reset-synchronized PWM mode and buffer mode are both selected, see section 10.4.8, Buffering. Rev. 2.0, 03/01, page 361 of 822 10.4.6 Complementary PWM Mode In complementary PWM mode channels 3 and 4 are combined to output three pairs of complementary, non-overlapping PWM waveforms. When complementary PWM mode is selected TIOCA3, TIOCB3, TIOCA4, TOCXA4, TIOCB4, and TOCXB4 automatically become PWM output pins, and TCNT3 and TCNT4 function as up/downcounters. Table 10.7 lists the PWM output pins. Table 10.8 summarizes the register settings. Table 10.7 Channel 3 Output Pins in Complementary PWM Mode Output Pin TIOCA3 TIOCB3 Description PWM output 1 PWM output 1' (non-overlapping complementary waveform to PWM output 1) PWM output 2 PWM output 2' (non-overlapping complementary waveform to PWM output 2) PWM output 3 PWM output 3' (non-overlapping complementary waveform to PWM output 3) 4 TIOCA4 TOCXA4 TIOCB4 TOCXB4 Table 10.8 Register TCNT3 TCNT4 GRA3 GRB3 GRA4 GRB4 Register Settings in Complementary PWM Mode Setting Initially specifies the non-overlap margin (difference to TCNT4) Initially set to H'0000 Specifies the upper limit value of TCNT3 minus 1 Specifies a transition point of PWM waveforms output from TIOCA3 and TIOCB3 Specifies a transition point of PWM waveforms output from TIOCA4 and TOCXA4 Specifies a transition point of PWM waveforms output from TIOCB4 and TOCXB4 Rev. 2.0, 03/01, page 362 of 822 Setup Procedure for Complementary PWM Mode: Figure 10.33 shows a sample procedure for setting up complementary PWM mode. Complementary PWM mode 1. Clear bits STR3 and STR4 to 0 in TSTR to halt the timer counters. Complementary PWM mode must be set up while TCNT3 and TCNT4 are halted. 1 2. Set bits TPSC2 to TPSC0 in TCR to select the same counter clock source for channels 3 and 4. If an external clock source is selected, select the external clock edge(s) with bits CKEG1 and CKEG0 in TCR. Do not select any counter clear source with bits CCLR1 and CCLR0 in TCR. 3. Set bits CMD1 and CMD0 in TFCR to select complementary PWM mode. TIOCA3, TIOCB3, TIOCA4, TIOCB4, TOCXA4, and TOCXB4 automatically become PWM output pins. 4. Clear TCNT4 to H'0000. Set the nonoverlap margin in TCNT3. Do not set TCNT3 and TCNT4 to the same value. 5. GRA3 is the waveform period register. Set the upper limit value of TCNT3 minus 1 in GRA3. Set transition times of the PWM output waveforms in GRB3, GRA4, and GRB4. Set times within the compare match range of TCNT3 and TCNT4. T X (X: initial setting of GRB3, GRA4, or GRB4. T: initial setting of TCNT3) 6. Set bits STR3 and STR4 in TSTR to 1 to start TCNT3 and TCNT4. Stop counting Select counter clock 2 Select complementary PWM mode 3 Set TCNTs 4 Set general registers 5 Start counters 6 Complementary PWM mode Note: After exiting complementary PWM mode, to resume operating in complementary PWM mode, follow the entire setup procedure from step 1 again. Figure 10.33 Setup Procedure for Complementary PWM Mode (Example) Rev. 2.0, 03/01, page 363 of 822 Clearing Procedure for Complementary PWM Mode: Figure 10.34 shows the steps to clear complementary PWM mode. Complementary PWM mode 1. Clear the CMD1 bit of TFCR to 0 to set channels 3 and 4 to normal operating mode. 1 2. After setting channels 3 and 4 to normal operating mode, wait at least one counter clock period, then clear bits STR3 and STR4 of TSTR to 0 to stop counter operation of TCNT3 and TCNT4. Clear complementary PWM mode Stop counter operation 2 Normal operating mode Figure 10.34 Clearing Procedure for Complementary PWM Mode Rev. 2.0, 03/01, page 364 of 822 Examples of Complementary PWM Mode: Figure 10.35 shows an example of operation in complementary PWM mode. TCNT3 and TCNT4 operate as up/down-counters, counting down from compare match between TCNT3 and GRA3 and counting up from the point at which TCNT4 underflows. During each up-and-down counting cycle, PWM waveforms are generated by compare match with general registers GRB3, GRA4, and GRB4. Since TCNT3 is initially set to a higher value than TCNT4, compare match events occur in the sequence TCNT3, TCNT4, TCNT4, TCNT3. TCNT3 and TCNT4 values GRA3 Down-counting starts at compare match between TCNT3 and GRA3 TCNT3 GRB3 GRA4 GRB4 H'0000 Up-counting starts when TCNT4 underflows TCNT4 Time TIOCA3 TIOCB3 TIOCA4 TOCXA4 TIOCB4 TOCXB4 Figure 10.35 Operation in Complementary PWM Mode (Example 1, OLS3 = OLS4 = 1) Rev. 2.0, 03/01, page 365 of 822 Figure 10.36 shows examples of waveforms with 0% and 100% duty cycles (in one phase) in complementary PWM mode. In this example the outputs change at compare match with GRB3, so waveforms with duty cycles of 0% or 100% can be output by setting GRB3 to a value larger than GRA3. The duty cycle can be changed easily during operation by use of the buffer registers. For further information see section 10.4.8, Buffering. TCNT3 and TCNT4 values GRA3 GRB3 H'0000 TIOCA3 TIOCB3 0% duty cycle a. 0% duty cycle TCNT3 and TCNT4 values GRA3 Time GRB3 H'0000 TIOCA3 TIOCB3 100% duty cycle b. 100% duty cycle Time Figure 10.36 Operation in Complementary PWM Mode (Example 2, OLS3 = OLS4 = 1) Rev. 2.0, 03/01, page 366 of 822 In complementary PWM mode, TCNT3 and TCNT4 overshoot and undershoot at the transitions between up-counting and down-counting. The setting conditions for the IMFA bit in channel 3 and the OVF bit in channel 4 differ from the usual conditions. In buffered operation the buffer transfer conditions also differ. Timing diagrams are shown in figures 10.37 and 10.38. TCNT3 N-1 N N+1 N N-1 GRA3 N IMFA Set to 1 Buffer transfer signal (BR to GR) Flag not set GR Buffer transfer No buffer transfer Figure 10.37 Overshoot Timing Rev. 2.0, 03/01, page 367 of 822 Underflow TCNT4 H'0001 H'0000 H'FFFF Overflow H'0000 OVF Set to 1 Buffer transfer signal (BR to GR) Flag not set GR Buffer transfer No buffer transfer Figure 10.38 Undershoot Timing In channel 3, IMFA is set to 1 only during up-counting. In channel 4, OVF is set to 1 only when an underflow occurs. When buffering is selected, buffer register contents are transferred to the general register at compare match A3 during up-counting, and when TCNT4 underflows. General Register Settings in Complementary PWM Mode: When setting up general registers for complementary PWM mode or changing their settings during operation, note the following points. * Initial settings Do not set values from H'0000 to T - 1 (where T is the initial value of TCNT3). After the counters start and the first compare match A3 event has occurred, however, settings in this range also become possible. * Changing settings Use the buffer registers. Correct waveform output may not be obtained if a general register is written to directly. * Cautions on changes of general register settings Rev. 2.0, 03/01, page 368 of 822 GRA3 GR H'0000 BR Not allowed GR Figure 10.39 Changing a General Register Setting by Buffer Transfer (Example 1) Buffer transfer at transition from up-counting to down-counting If the general register value is in the range from GRA3 - T + 1 to GRA3, do not transfer a buffer register value outside this range. Conversely, if the general register value is outside this range, do not transfer a value within this range. See figure 10.40. GRA3 + 1 GRA3 Illegal changes GRA3 - T + 1 GRA3 - T TCNT3 TCNT4 Figure 10.40 Changing a General Register Setting by Buffer Transfer (Caution 1) Buffer transfer at transition from down-counting to up-counting If the general register value is in the range from H'0000 to T - 1, do not transfer a buffer register value outside this range. Conversely, when a general register value is outside this range, do not transfer a value within this range. See figure 10.41. Rev. 2.0, 03/01, page 369 of 822 TCNT3 TCNT4 T T-1 Illegal changes H'0000 H'FFFF Figure 10.41 Changing a General Register Setting by Buffer Transfer (Caution 2) General register settings outside the counting range (H'0000 to GRA3) Waveforms with a duty cycle of 0% or 100% can be output by setting a general register to a value outside the counting range. When a buffer register is set to a value outside the counting range, then later restored to a value within the counting range, the counting direction (up or down) must be the same both times. See figure 10.42. GRA3 GR H'0000 0% duty cycle Output pin Output pin 100% duty cycle BR GR Write during down-counting Write during up-counting Figure 10.42 Changing a General Register Setting by Buffer Transfer (Example 2) Settings can be made in this way by detecting GRA3 compare match or TCNT4 underflow before writing to the buffer register. They can also be made by using GRA3 compare match to activate the DMAC. Rev. 2.0, 03/01, page 370 of 822 10.4.7 Phase Counting Mode In phase counting mode the phase difference between two external clock inputs (at the TCLKA and TCLKB pins) is detected, and TCNT2 counts up or down accordingly. In phase counting mode, the TCLKA and TCLKB pins automatically function as external clock input pins and TCNT2 becomes an up/down-counter, regardless of the settings of bits TPSC2 to TPSC0, CKEG1, and CKEG0 in TCR2. Settings of bits CCLR1, CCLR0 in TCR2, and settings in TIOR2, TIER2, TSR2, GRA2, and GRB2 are valid. The input capture and output compare functions can be used, and interrupts can be generated. Phase counting is available only in channel 2. Sample Setup Procedure for Phase Counting Mode: Figure 10.43 shows a sample procedure for setting up phase counting mode. Phase counting mode 1. Set the MDF bit in TMDR to 1 to select phase counting mode. 2. Select the flag setting condition with the FDIR bit in TMDR. 3. Set the STR2 bit to 1 in TSTR to start the timer counter. Select phase counting mode 1 Select flag setting condition 2 Start counter 3 Phase counting mode Figure 10.43 Setup Procedure for Phase Counting Mode (Example) Rev. 2.0, 03/01, page 371 of 822 Example of Phase Counting Mode: Figure 10.44 shows an example of operations in phase counting mode. Table 10.9 lists the up-counting and down-counting conditions for TCNT2. In phase counting mode both the rising and falling edges of TCLKA and TCLKB are counted. The phase difference between TCLKA and TCLKB must be at least 1.5 states, the phase overlap must also be at least 1.5 states, and the pulse width must be at least 2.5 states. See figure 10.45. TCNT2 value Counting up Counting down Time TCLKB TCLKA Figure 10.44 Operation in Phase Counting Mode (Example) Table 10.9 Up/Down Counting Conditions Counting Direction TCLKB TCLKA Up-Counting Low High High Low Down-Counting High Low Low High Phase difference Phase difference Pulse width Pulse width TCLKA TCLKB Phase difference and overlap: at least 1.5 states Pulse width: at least 2.5 states Overlap Overlap Figure 10.45 Phase Difference, Overlap, and Pulse Width in Phase Counting Mode Rev. 2.0, 03/01, page 372 of 822 10.4.8 Buffering Buffering operates differently depending on whether a general register is an output compare register or an input capture register, with further differences in reset-synchronized PWM mode and complementary PWM mode. Buffering is available only in channels 3 and 4. Buffering operations under the conditions mentioned above are described next. * General register used for output compare The buffer register value is transferred to the general register at compare match. See figure 10.46. Compare match signal BR GR Comparator TCNT Figure 10.46 Compare Match Buffering * General register used for input capture The TCNT value is transferred to the general register at input capture. The previous general register value is transferred to the buffer register. See figure 10.47. Input capture signal BR GR TCNT Figure 10.47 Input Capture Buffering Rev. 2.0, 03/01, page 373 of 822 * Complementary PWM mode The buffer register value is transferred to the general register when TCNT3 and TCNT4 change counting direction. This occurs at the following two times: When TCNT3 compare matches GRA3 When TCNT4 underflows * Reset-synchronized PWM mode The buffer register value is transferred to the general register at compare match A3. Sample Buffering Setup Procedure: Figure 10.48 shows a sample buffering setup procedure. Buffering 1. Set TIOR to select the output compare or input capture function of the general registers. 1 2. Set bits BFA3, BFA4, BFB3, and BFB4 in TFCR to select buffering of the required general registers. 3. Set the STR bits to 1 in TSTR to start the timer counters. Select general register functions Set buffer bits 2 Start counters 3 Buffered operation Figure 10.48 Buffering Setup Procedure (Example) Rev. 2.0, 03/01, page 374 of 822 Examples of Buffering: Figure 10.49 shows an example in which GRA is set to function as an output compare register buffered by BRA, TCNT is set to operate as a periodic counter cleared by GRB compare match, and TIOCA and TIOCB are set to toggle at compare match A and B. Because of the buffer setting, when TIOCA toggles at compare match A, the BRA value is simultaneously transferred to GRA. This operation is repeated each time compare match A occurs. Figure 10.50 shows the transfer timing. TCNT value GRB H'0250 H'0200 H'0100 H'0000 BRA GRA TIOCB TIOCA H'0200 H'0250 Counter cleared by compare match B Time H'0100 H'0200 H'0100 H'0200 H'0200 Toggle output Toggle output Compare match A Figure 10.49 Register Buffering (Example 1: Buffering of Output Compare Register) Rev. 2.0, 03/01, page 375 of 822  TCNT Compare match signal Buffer transfer signal BR GR n N N n n+1 Figure 10.50 Compare Match and Buffer Transfer Timing (Example) Rev. 2.0, 03/01, page 376 of 822 Figure 10.51 shows an example in which GRA is set to function as an input capture register buffered by BRA, and TCNT is cleared by input capture B. The falling edge is selected as the input capture edge at TIOCB. Both edges are selected as input capture edges at TIOCA. Because of the buffer setting, when the TCNT value is captured into GRA at input capture A, the previous GRA value is simultaneously transferred to BRA. Figure 10.52 shows the transfer timing. TCNT value H'0180 H'0160 Counter cleared by input capture B H'0005 H'0000 TIOCB Time TIOCA GRA H'0005 H'0160 BRA H'0005 H'0160 GRB H'0180 Input capture A Figure 10.51 Register Buffering (Example 2: Buffering of Input Capture Register) Rev. 2.0, 03/01, page 377 of 822  TIOC pin Input capture signal TCNT GR BR M m n n M n+1 N n M N n N+1 Figure 10.52 Input Capture and Buffer Transfer Timing Rev. 2.0, 03/01, page 378 of 822 Figure 10.53 shows an example in which GRB3 is buffered by BRB3 in complementary PWM mode. Buffering is used to set GRB3 to a higher value than GRA3, generating a PWM waveform with 0% duty cycle. The BRB3 value is transferred to GRB3 when TCNT3 matches GRA3, and when TCNT4 underflows. TCNT3 and TCNT4 values H'1FFF GRA3 TCNT3 TCNT4 GRB3 H'0999 H'0000 Time BRB3 GRB3 H'0999 H'0999 H'0999 H'1FFF H'1FFF H'1FFF H'0999 H'0999 TIOCA3 TIOCB3 Figure 10.53 Register Buffering (Example 3: Buffering in Complementary PWM Mode) Rev. 2.0, 03/01, page 379 of 822 10.4.9 ITU Output Timing The ITU outputs from channels 3 and 4 can be disabled by bit settings in TOER or by an external trigger, or inverted by bit settings in TOCR. Timing of Enabling and Disabling of ITU Output by TOER: In this example an ITU output is disabled by clearing a master enable bit to 0 in TOER. An arbitrary value can be output by appropriate settings of the data register (DR) and data direction register (DDR) of the corresponding input/output port. Figure 10.54 illustrates the timing of the enabling and disabling of ITU output by TOER. T1 T2 T3 Address bus TOER address TOER ITU output pin Timer output I/O port ITU output Generic input/output Figure 10.54 Timing of Disabling of ITU Output by Writing to TOER (Example) Rev. 2.0, 03/01, page 380 of 822 Timing of Disabling of ITU Output by External Trigger: If the XTGD bit is cleared to 0 in TOCR in reset-synchronized PWM mode or complementary PWM mode, when an input capture A signal occurs in channel 1, the master enable bits are cleared to 0 in TOER, disabling ITU output. Figure 10.55 shows the timing. TIOCA1 pin Input capture signal TOER ITU output pins N ITU output ITU output N: Arbitrary setting (H'C1 to H'FF) H'C0 I/O port Generic input/output N ITU output ITU output H'C0 I/O port Generic input/output Figure 10.55 Timing of Disabling of ITU Output by External Trigger (Example) Timing of Output Inversion by TOCR: The output levels in reset-synchronized PWM mode and complementary PWM mode can be inverted by inverting the output level select bits (OLS4 and OLS3) in TOCR. Figure 10.56 shows the timing. T1 T2 T3 Address bus TOCR address TOCR ITU output pin Inverted Figure 10.56 Timing of Inverting of ITU Output Level by Writing to TOCR (Example) Rev. 2.0, 03/01, page 381 of 822 10.5 Interrupts The ITU has two types of interrupts: input capture/compare match interrupts, and overflow interrupts. 10.5.1 Setting of Status Flags Timing of Setting of IMFA and IMFB at Compare Match: IMFA and IMFB are set to 1 by a compare match signal generated when TCNT matches a general register (GR). The compare match signal is generated in the last state in which the values match (when TCNT is updated from the matching count to the next count). Therefore, when TCNT matches a general register, the compare match signal is not generated until the next timer clock input. Figure 10.57 shows the timing of the setting of IMFA and IMFB. TCNT input clock TCNT N N+1 GR N Compare match signal IMF IMI Figure 10.57 Timing of Setting of IMFA and IMFB by Compare Match Rev. 2.0, 03/01, page 382 of 822 Timing of Setting of IMFA and IMFB by Input Capture: IMFA and IMFB are set to 1 by an input capture signal. The TCNT contents are simultaneously transferred to the corresponding general register. Figure 10.58 shows the timing. Input capture signal IMF TCNT N GR N IMI Figure 10.58 Timing of Setting of IMFA and IMFB by Input Capture Rev. 2.0, 03/01, page 383 of 822 Timing of Setting of Overflow Flag (OVF): OVF is set to 1 when TCNT overflows from H'FFFF to H'0000 or underflows from H'0000 to H'FFFF. Figure 10.59 shows the timing. TCNT H'FFFF H'0000 Overflow signal OVF OVI Figure 10.59 Timing of Setting of OVF 10.5.2 Clearing of Status Flags If the CPU reads a status flag while it is set to 1, then writes 0 in the status flag, the status flag is cleared. Figure 10.60 shows the timing. TSR write cycle T1 T2 T3 Address TSR address IMF, OVF Figure 10.60 Timing of Clearing of Status Flags Rev. 2.0, 03/01, page 384 of 822 10.5.3 Interrupt Sources and DMA Controller Activation Each ITU channel can generate a compare match/input capture A interrupt, a compare match/input capture B interrupt, and an overflow interrupt. In total there are 15 interrupt sources, all independently vectored. An interrupt is requested when the interrupt request flag and interrupt enable bit are both set to 1. The priority order of the channels can be modified in interrupt priority registers A and B (IPRA and IPRB). For details see section 5, Interrupt Controller. Compare match/input capture A interrupts in channels 0 to 3 can activate the DMA controller (DMAC). When the DMAC is activated a CPU interrupt is not requested. Table 10.10 lists the interrupt sources. Table 10.10 ITU Interrupt Sources Channel 0 Interrupt Source IMIA0 IMIB0 OVI0 1 IMIA1 IMIB1 OVI1 2 IMIA2 IMIB2 OVI2 3 IMIA3 IMIB3 OVI3 4 IMIA4 IMIB4 OVI4 Description Compare match/input capture A0 Compare match/input capture B0 Overflow 0 Compare match/input capture A1 Compare match/input capture B1 Overflow 1 Compare match/input capture A2 Compare match/input capture B2 Overflow 2 Compare match/input capture A3 Compare match/input capture B3 Overflow 3 Compare match/input capture A4 Compare match/input capture B4 Overflow 4 DMAC Activatable Yes No No Yes No No Yes No No Yes No No No No No Priority* High Low Note: * The priority immediately after a reset is indicated. Inter-channel priorities can be changed by settings in IPRA and IPRB. Rev. 2.0, 03/01, page 385 of 822 10.6 Usage Notes This section describes contention and other matters requiring special attention during ITU operations. Contention between TCNT Write and Clear: If a counter clear signal occurs in the T 3 state of a TCNT write cycle, clearing of the counter takes priority and the write is not performed. See figure 10.61. TCNT write cycle T1 T2 T3 Address bus TCNT address Internal write signal Counter clear signal TCNT N H'0000 Figure 10.61 Contention between TCNT Write and Clear Rev. 2.0, 03/01, page 386 of 822 Contention between TCNT Word Write and Increment: If an increment pulse occurs in the T3 state of a TCNT word write cycle, writing takes priority and TCNT is not incremented. See figure 10.62. TCNT word write cycle T1 T2 T3 Address bus TCNT address Internal write signal TCNT input clock TCNT N M TCNT write data Figure 10.62 Contention between TCNT Word Write and Increment Rev. 2.0, 03/01, page 387 of 822 Contention between TCNT Byte Write and Increment: If an increment pulse occurs in the T2 or T3 state of a TCNT byte write cycle, writing takes priority and TCNT is not incremented. The TCNT byte that was not written retains its previous value. See figure 10.63, which shows an increment pulse occurring in the T2 state of a byte write to TCNTH. TCNTH byte write cycle T1 T2 T3 Address bus TCNTH address Internal write signal TCNT input clock TCNTH N TCNT write data M TCNTL X X+1 X Figure 10.63 Contention between TCNT Byte Write and Increment Rev. 2.0, 03/01, page 388 of 822 Contention between General Register Write and Compare Match: If a compare match occurs in the T3 state of a general register write cycle, writing takes priority and the compare match signal is inhibited. See figure 10.64. General register write cycle T1 T2 T3 Address bus GR address Internal write signal TCNT N N+1 GR N M General register write data Compare match signal Inhibited Figure 10.64 Contention between General Register Write and Compare Match Rev. 2.0, 03/01, page 389 of 822 Contention between TCNT Write and Overflow or Underflow: If an overflow occurs in the T 3 state of a TCNT write cycle, writing takes priority and the counter is not incremented. OVF is set to 1.The same holds for underflow. See figure 10.65. TCNT write cycle T1 T2 T3 Address bus TCNT address Internal write signal TCNT input clock Overflow signal TCNT H'FFFF TCNT write data M OVF Figure 10.65 Contention between TCNT Write and Overflow Rev. 2.0, 03/01, page 390 of 822 Contention between General Register Read and Input Capture: If an input capture signal occurs during the T3 state of a general register read cycle, the value before input capture is read. See figure 10.66. General register read cycle T1 T2 T3 Address bus GR address Internal read signal Input capture signal GR X M Internal data bus X Figure 10.66 Contention between General Register Read and Input Capture Rev. 2.0, 03/01, page 391 of 822 Contention between Counter Clearing by Input Capture and Counter Increment: If an input capture signal and counter increment signal occur simultaneously, the counter is cleared according to the input capture signal. The counter is not incremented by the increment signal. The value before the counter is cleared is transferred to the general register. See figure 10.67. Input capture signal Counter clear signal TCNT input clock TCNT N H'0000 GR N Figure 10.67 Contention between Counter Clearing by Input Capture and Counter Increment Rev. 2.0, 03/01, page 392 of 822 Contention between General Register Write and Input Capture: If an input capture signal occurs in the T3 state of a general register write cycle, input capture takes priority and the write to the general register is not performed. See figure 10.68. General register write cycle T1 T2 T3 Address bus GR address Internal write signal Input capture signal TCNT M GR M Figure 10.68 Contention between General Register Write and Input Capture Note on Waveform Period Setting: When a counter is cleared by compare match, the counter is cleared in the last state at which the TCNT value matches the general register value, at the time when this value would normally be updated to the next count. The actual counter frequency is therefore given by the following formula: f= (N + 1) (f: counter frequency. : system clock frequency. N: value set in general register.) Rev. 2.0, 03/01, page 393 of 822 Contention between Buffer Register Write and Input Capture: If a buffer register is used for input capture buffering and an input capture signal occurs in the T3 state of a write cycle, input capture takes priority and the write to the buffer register is not performed. See figure 10.69. Buffer register write cycle T1 T2 T3 Address bus BR address Internal write signal Input capture signal GR N X TCNT value BR M N Figure 10.69 Contention between Buffer Register Write and Input Capture Rev. 2.0, 03/01, page 394 of 822 Note on Write Operations when Using Synchronous Operation: When channels are synchronized, if a TCNT value is modified by byte write access, all 16 bits of all synchronized counters assume the same value as the counter that was addressed. Example: When channels 2 and 3 are synchronized * Byte write to channel 2 or byte write to channel 3 Write A to upper byte of channel 2 TCNT2 TCNT3 W Y X Z TCNT2 TCNT3 A A X X Upper byte Lower byte Write A to lower byte of channel 3 TCNT2 TCNT3 Upper byte Lower byte Y Y A A Upper byte Lower byte * Word write to channel 2 or word write to channel 3 TCNT2 TCNT3 W Y X Z Write AB word to channel 2 or 3 TCNT2 TCNT3 A A B B Upper byte Lower byte Upper byte Lower byte Note on Setup of Reset-Synchronized PWM Mode and Complementary PWM Mode: When setting bits CMD1 and CMD0 in TFCR, take the following precautions: * Write to bits CMD1 and CMD0 only when TCNT3 and TCNT4 are stopped. * Do not switch directly between reset-synchronized PWM mode and complementary PWM mode. First switch to normal mode (by clearing bit CMD1 to 0), then select reset-synchronized PWM mode or complementary PWM mode. Rev. 2.0, 03/01, page 395 of 822 Register Settings TMDR TFCR TOCR TOER TIOR0 TCR0 TSNC Operating Mode MDF FDIR PWM Master Enable IOA IOB -- -- -- IOA2 = 0 Other bits unrestricted IOB2 = 0 Other bits unrestricted IOA2 = 1 Other bits unrestricted IOB2 = 1 Other bits unrestricted -- CCLR1 = 0 CCLR0 = 1 -- -- CCLR1 = 1 CCLR0 = 0 -- -- -- CCLR1 = 1 CCLR0 = 1 -- * Clear Select Clock Select Synchronization -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- PWM0 = 1 -- -- PWM0 = 0 -- -- -- -- ResetOutput CompleSynchro- BufferXTGD Level mentary nized ing Select PWM PWM Synchronous preset SYNC0 = 1 ITU Operating Modes PWM mode Output compare A Rev. 2.0, 03/01, page 396 of 822 -- -- -- -- -- -- -- -- -- -- PWM0 = 0 -- -- -- -- -- -- -- -- PWM0 = 0 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Output compare B Input capture A Table 10.11 (1) ITU Operating Modes (Channel 0) Input capture B Counter By compare clearing match/input capture A By compare match/input capture B Synchronous clear SYNC0 = 1 Legend: Setting available (valid). -- Setting does not affect this mode. Note: * The input capture function cannot be used in PWM mode. If compare match A and compare match B occur simultaneously, the compare match signal is inhibited. Register Settings TSNC TMDR TFCR TOCR TOER TIOR1 TCR1 Operating Mode MDF FDIR PWM Master Enable IOA IOB -- -- -- IOA2 = 0 Other bits unrestricted IOB2 = 0 Other bits unrestricted IOA2 = 1 Other bits unrestricted -- IOB2 = 1 Other bits unrestricted -- -- -- *1 Synchronization -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- PWM1 = 1 -- -- PWM1 = 0 -- -- -- -- ResetOutput CompleSynchro- BufferXTGD Level mentary nized ing Select PWM PWM Clear Select Clock Select Synchronous preset SYNC1 = 1 PWM mode Output compare A Output compare B -- -- -- -- -- -- -- -- Input capture A -- -- PWM1 = 0 -- -- -- -- -- *2 Input capture B -- -- PWM1 = 0 -- -- -- -- -- Table 10.11 (2) ITU Operating Modes (Channel 1) Counter By compare clearing match/input capture A -- -- -- -- -- -- -- -- -- -- -- CCLR1 = 0 CCLR0 = 1 -- -- -- CCLR1 = 1 CCLR0 = 0 By compare match/input capture B -- -- -- -- Synchronous clear SYNC1 = 1 -- -- -- -- CCLR1 = 1 CCLR0 = 1 Legend: Setting available (valid). -- Setting does not affect this mode. Rev. 2.0, 03/01, page 397 of 822 Notes: 1. The input capture function cannot be used in PWM mode. If compare match A and compare match B occur simultaneously, the compare match signal is inhibited. 2. Valid only when channels 3 and 4 are operating in complementary PWM mode or reset-synchronized PWM mode. Register Settings TSNC TMDR TFCR TOCR TOER TIOR2 TCR2 Operating Mode MDF FDIR PWM Master Enable IOA IOB -- -- -- IOA2 = 0 Other bits unrestricted IOB2 = 0 Other bits unrestricted IOA2 = 1 Other bits unrestricted -- IOB2 = 1 Other bits unrestricted -- -- CCLR1 = 0 CCLR0 = 1 -- -- -- CCLR1 = 1 CCLR0 = 0 -- -- -- -- CCLR1 = 1 CCLR0 = 1 -- -- -- -- -- -- * Clear Select Synchronization -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- PWM2 = 1 -- -- PWM2 = 0 -- -- -- -- ResetOutput CompleSynchro- BufferXTGD Level mentary nized ing Select PWM PWM Clock Select Synchronous preset SYNC2 = 1 PWM mode Output compare A Rev. 2.0, 03/01, page 398 of 822 -- -- -- -- -- -- -- -- -- -- PWM2 = 0 -- -- -- -- -- -- -- -- PWM2 = 0 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- MDF = 1 -- -- Output compare B Input capture A Table 10.11 (3) ITU Operating Modes (Channel 2) Input capture B Counter By compare clearing match/input capture A By compare match/input capture B Synchronous clear SYNC2 = 1 Phase counting mode Legend: Setting available (valid). -- Setting does not affect this mode. Note: * The input capture function cannot be used in PWM mode. If compare match A and compare match B occur simultaneously, the compare match signal is inhibited. Register Settings TMDR PWM *3 TSNC Complementary PWM Buffering IOA IOB -- CMD1 = 0 CMD1 = 0 IOA2 = 0 Other bits unrestricted IOB2 = 0 Other bits unrestricted EA3 ignored IOA2 = 1 Other bits Other bits unrestricted unrestricted EB3 ignored Other bits unrestricted *1 TFCR ResetSynchronized PWM Output XTGD Level Select Master Enable *1 TOCR Clear Select TOER TIOR3 TCR3 Clock Select Operating Mode Synchro- MDF FDIR nization -- -- -- PWM3 = 1 CMD1 = 0 PWM3 = 0 CMD1 = 0 -- -- -- -- -- -- *2 Synchronous preset -- -- -- SYNC3 = 1 PWM mode Output compare A Output compare B -- -- CMD1 = 0 CMD1 = 0 -- -- Input capture A -- -- PWM3 = 0 CMD1 = 0 CMD1 = 0 -- -- Input capture B -- -- PWM3 = 0 CMD1 = 0 CMD1 = 0 -- -- IOB2 = 1 Other bits unrestricted CCLR1 = 0 CCLR0 = 1 *1 Counter By compare clearing match/input capture A -- -- Illegal setting: CMD1 = 1 CMD0 = 0 CMD1 = 0 CMD1 = 0 -- -- -- -- -- -- *4 Table 10.11 (4) ITU Operating Modes (Channel 3) By compare match/input capture B -- -- Illegal setting: CMD1 = 1 CMD0 = 0 -- CMD1 = 1 CMD0 = 0 CMD1 = 1 CMD0 = 1 CMD1 = 1 CMD0 = 1 BFA3 = 1 Other bits unrestricted BFB3 = 1 Other bits unrestricted CMD1 = 1 CMD0 = 0 -- -- CCLR1 = 1 CCLR0 = 0 -- *1 Synchronous clear *3 SYNC3 = 1 CCLR1 = 1 CCLR0 = 1 *6 *6 Complementary PWM mode -- -- -- -- -- -- -- -- -- -- *1 -- -- CCLR1 = 0 CCLR0 = 0 CCLR1 = 0 CCLR0 = 1 *5 Reset-synchronized PWM mode Buffering (BRA) -- -- Buffering (BRB) -- -- *1 Legend: Setting available (valid). -- Setting does not affect this mode. Rev. 2.0, 03/01, page 399 of 822 Notes: 1. 2. 3. 4. 5. 6. Master enable bit settings are valid only during waveform output. The input capture function cannot be used in PWM mode. If compare match A and compare match B occur simultaneously, the compare match signal is inhibited. Do not set both channels 3 and 4 for synchronous operation when complementary PWM mode is selected. The counter cannot be cleared by input capture A when reset-synchronized PWM mode is selected. In complementary PWM mode, select the same clock source for channels 3 and 4. Use the input capture A function in channel 1. Register Settings TMDR PWM *3 TSNC Complementary PWM Buffering IOA IOB -- CMD1 = 0 CMD1 = 0 -- IOA2 = 0 Other bits unrestricted IOB2 = 0 Other bits unrestricted EA4 ignored IOA2 = 1 Other bits Other bits unrestricted unrestricted EB4 ignored Other bits unrestricted *1 TFCR ResetSynchronized PWM Output XTGD Level Select Master Enable *1 TOCR Clear Select TOER TIOR4 TCR4 Clock Select Operating Mode Synchro- MDF FDIR nization -- -- -- PWM4 = 1 CMD1 = 0 PWM4 = 0 CMD1 = 0 -- -- -- -- -- *2 Synchronous preset -- -- -- SYNC4 = 1 PWM mode Output compare A Output compare B -- -- CMD1 = 0 CMD1 = 0 -- -- Rev. 2.0, 03/01, page 400 of 822 -- -- PWM4 = 0 CMD1 = 0 CMD1 = 0 -- -- -- -- PWM4 = 0 CMD1 = 0 CMD1 = 0 -- -- IOB2 = 1 Other bits unrestricted CCLR1 = 0 CCLR0 = 1 *1 Input capture A Input capture B Counter By compare clearing match/input capture A -- -- Illegal setting: CMD1 = 1 CMD0 = 0 Illegal setting: CMD1 = 1 CMD0 = 0 Illegal setting: CMD1 = 1 CMD0 = 0 -- CMD1 = 1 CMD0 = 0 CMD1 = 1 CMD0 = 1 CMD1 = 1 CMD0 = 1 BFA4 = 1 Other bits unrestricted BFB4 = 1 Other bits unrestricted -- -- CMD1 = 1 CMD0 = 0 -- *4 *4 *4 -- -- Table 10.11 (5) ITU Operating Modes (Channel 4) By compare match/input capture B -- -- -- -- -- -- -- CCLR1 = 1 CCLR0 = 0 -- *1 Synchronous clear *3 SYNC4 = 1 CCLR1 = 1 CCLR0 = 1 -- -- *1 Complementary PWM mode -- -- -- -- -- -- -- -- CCLR1 = 0 CCLR0 = 0 *6 *5 Reset-synchronized PWM mode *6 Buffering (BRA) -- -- Buffering (BRB) -- -- *1 Legend: Setting available (valid). -- Setting does not affect this mode. Notes: 1. 2. 3. 4. 5. 6. Master enable bit settings are valid only during waveform output. The input capture function cannot be used in PWM mode. If compare match A and compare match B occur simultaneously, the compare match signal is inhibited. Do not set both channels 3 and 4 for synchronous operation when complementary PWM mode is selected. When reset-synchronized PWM mode is selected, TCNT4 operates independently and the counter clearing function is available. Waveform output is not affected. In complementary PWM mode, select the same clock source for channels 3 and 4. TCR4 settings are valid in reset-synchronized PWM mode, but TCNT4 operates independently, without affecting waveform output. Section 11 Programmable Timing Pattern Controller 11.1 Overview The H8/3052F has a built-in programmable timing pattern controller (TPC) that provides pulse outputs by using the 16-bit integrated timer unit (ITU) as a time base. The TPC pulse outputs are divided into 4-bit groups (group 3 to group 0) that can operate simultaneously and independently. 11.1.1 Features TPC features are listed below. * 16-bit output data Maximum 16-bit data can be output. TPC output can be enabled on a bit-by-bit basis. * Four output groups Output trigger signals can be selected in 4-bit groups to provide up to four different 4-bit outputs. * Selectable output trigger signals Output trigger signals can be selected for each group from the compare-match signals of four ITU channels. * Non-overlap mode A non-overlap margin can be provided between pulse outputs. * Can operate together with the DMA controller (DMAC) The compare-match signals selected as trigger signals can activate the DMAC for sequential output of data without CPU intervention. Rev. 2.0, 03/01, page 401 of 822 11.1.2 Block Diagram Figure 11.1 shows a block diagram of the TPC. ITU compare match signals PADDR Control logic NDERA TPMR PBDDR NDERB TPCR TP15 TP14 TP13 TP12 TP11 TP10 TP 9 TP 8 TP 7 TP 6 TP 5 TP 4 TP 3 TP 2 TP 1 TP 0 Legend TPMR: TPCR: NDERB: NDERA: PBDDR: PADDR: NDRB: NDRA: PBDR: PADR: Pulse output pins, group 3 PBDR Pulse output pins, group 2 NDRB Internal data bus Pulse output pins, group 1 PADR Pulse output pins, group 0 NDRA TPC output mode register TPC output control register Next data enable register B Next data enable register A Port B data direction register Port A data direction register Next data register B Next data register A Port B data register Port A data register Figure 11.1 TPC Block Diagram Rev. 2.0, 03/01, page 402 of 822 11.1.3 Pin Configuration Table 11.1 summarizes the TPC output pins. Table 11.1 TPC Pins Name TPC output 0 TPC output 1 TPC output 2 TPC output 3 TPC output 4 TPC output 5 TPC output 6 TPC output 7 TPC output 8 TPC output 9 TPC output 10 TPC output 11 TPC output 12 TPC output 13 TPC output 14 TPC output 15 Symbol TP0 TP1 TP2 TP3 TP4 TP5 TP6 TP7 TP8 TP9 TP10 TP11 TP12 TP13 TP14 TP15 I/O Output Output Output Output Output Output Output Output Output Output Output Output Output Output Output Output Group 3 pulse output Group 2 pulse output Group 1 pulse output Function Group 0 pulse output Rev. 2.0, 03/01, page 403 of 822 11.1.4 Register Configuration Table 11.2 summarizes the TPC registers. Table 11.2 TPC Registers 1 Address* Name Port A data direction register Port A data register Port B data direction register Port B data register TPC output mode register TPC output control register Next data enable register B Next data enable register A Next data register A Next data register B Abbreviation PADDR PADR PBDDR PBDR TPMR TPCR NDERB NDERA NDRA NDRB R/W W 2 R/(W)* Initial Value H'00 H'00 H'00 H'00 H'F0 H'FF H'00 H'00 H'00 H'00 H'FFD1 H'FFD3 H'FFD4 H'FFD6 H'FFA0 H'FFA1 H'FFA2 H'FFA3 H'FFA5/ 3 H'FFA7* H'FFA4 3 H'FFA6* W 2 R/(W)* R/W R/W R/W R/W R/W R/W Notes: 1. Lower 16 bits of the address. 2. Bits used for TPC output cannot be written. 3. The NDRA address is H'FFA5 when the same output trigger is selected for TPC output groups 0 and 1 by settings in TPCR. When the output triggers are different, the NDRA address is H'FFA7 for group 0 and H'FFA5 for group 1. Similarly, the address of NDRB is H'FFA4 when the same output trigger is selected for TPC output groups 2 and 3 by settings in TPCR. When the output triggers are different, the NDRB address is H'FFA6 for group 2 and H'FFA4 for group 3. Rev. 2.0, 03/01, page 404 of 822 11.2 11.2.1 Register Descriptions Port A Data Direction Register (PADDR) PADDR is an 8-bit write-only register that selects input or output for each pin in port A. Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W PA7 DDR PA6 DDR PA5 DDR PA4 DDR PA3 DDR PA2 DDR PA1 DDR PA0 DDR Port A data direction 7 to 0 These bits select input or output for port A pins Port A is multiplexed with pins TP7 to TP0. Bits corresponding to pins used for TPC output must be set to 1. For further information about PADDR, see section 9.11, Port A. 11.2.2 Port A Data Register (PADR) PADR is an 8-bit readable/writable register that stores TPC output data for groups 0 and 1, when these TPC output groups are used. Bit Initial value Read/Write 7 PA 7 0 R/(W)* 6 PA 6 0 R/(W)* 5 PA 5 0 R/(W)* 4 PA 4 0 R/(W)* 3 PA 3 0 R/(W)* 2 PA 2 0 R/(W)* 1 PA 1 0 R/(W)* 0 PA 0 0 R/(W)* Port A data 7 to 0 These bits store output data for TPC output groups 0 and 1 Note: * Bits selected for TPC output by NDERA settings become read-only bits. For further information about PADR, see section 9.11, Port A. Rev. 2.0, 03/01, page 405 of 822 11.2.3 Port B Data Direction Register (PBDDR) PBDDR is an 8-bit write-only register that selects input or output for each pin in port B. Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W 2 0 W 1 0 W 0 0 W PB7 DDR PB6 DDR PB5 DDR PB4 DDR PB3 DDR PB2 DDR PB1 DDR PB0 DDR Port B data direction 7 to 0 These bits select input or output for port B pins Port B is multiplexed with pins TP15 to TP8. Bits corresponding to pins used for TPC output must be set to 1. For further information about PBDDR, see section 9.12, Port B. 11.2.4 Port B Data Register (PBDR) PBDR is an 8-bit readable/writable register that stores TPC output data for groups 2 and 3, when these TPC output groups are used. Bit Initial value Read/Write 7 PB 7 0 R/(W)* 6 PB 6 0 R/(W)* 5 PB 5 0 R/(W)* 4 PB 4 0 R/(W)* 3 PB 3 0 R/(W)* 2 PB 2 0 R/(W)* 1 PB 1 0 R/(W)* 0 PB 0 0 R/(W)* Port B data 7 to 0 These bits store output data for TPC output groups 2 and 3 Note: * Bits selected for TPC output by NDERB settings become read-only bits. For further information about PBDR, see section 9.12, Port B. Rev. 2.0, 03/01, page 406 of 822 11.2.5 Next Data Register A (NDRA) NDRA is an 8-bit readable/writable register that stores the next output data for TPC output groups 1 and 0 (pins TP7 to TP0). During TPC output, when an ITU compare match event specified in TPCR occurs, NDRA contents are transferred to the corresponding bits in PADR. The address of NDRA differs depending on whether TPC output groups 0 and 1 have the same output trigger or different output triggers. NDRA is initialized to H'00 by a reset and in hardware standby mode. It is not initialized in software standby mode. Same Trigger for TPC Output Groups 0 and 1: If TPC output groups 0 and 1 are triggered by the same compare match event, the NDRA address is H'FFA5. The upper 4 bits belong to group 1 and the lower 4 bits to group 0. Address H'FFA7 consists entirely of reserved bits that cannot be modified and are always read as 1. Address H'FFA5 Bit Initial value Read/Write 7 NDR7 0 R/W 6 NDR6 0 R/W 5 NDR5 0 R/W 4 NDR4 0 R/W 3 NDR3 0 R/W 2 NDR2 0 R/W 1 NDR1 0 R/W 0 NDR0 0 R/W Next data 7 to 4 These bits store the next output data for TPC output group 1 Next data 3 to 0 These bits store the next output data for TPC output group 0 Address H'FFA7 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Reserved bits Rev. 2.0, 03/01, page 407 of 822 Different Triggers for TPC Output Groups 0 and 1: If TPC output groups 0 and 1 are triggered by different compare match events, the address of the upper 4 bits of NDRA (group 1) is H'FFA5 and the address of the lower 4 bits (group 0) is H'FFA7. Bits 3 to 0 of address H'FFA5 and bits 7 to 4 of address H'FFA7 are reserved bits that cannot be modified and are always read as 1. Address H'FFA5 Bit Initial value Read/Write 7 NDR7 0 R/W 6 NDR6 0 R/W 5 NDR5 0 R/W 4 NDR4 0 R/W 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Next data 7 to 4 These bits store the next output data for TPC output group 1 Reserved bits Address H'FFA7 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 NDR3 0 R/W 2 NDR2 0 R/W 1 NDR1 0 R/W 0 NDR0 0 R/W Reserved bits Next data 3 to 0 These bits store the next output data for TPC output group 0 Rev. 2.0, 03/01, page 408 of 822 11.2.6 Next Data Register B (NDRB) NDRB is an 8-bit readable/writable register that stores the next output data for TPC output groups 3 and 2 (pins TP15 to TP8). During TPC output, when an ITU compare match event specified in TPCR occurs, NDRB contents are transferred to the corresponding bits in PBDR. The address of NDRB differs depending on whether TPC output groups 2 and 3 have the same output trigger or different output triggers. NDRB is initialized to H'00 by a reset and in hardware standby mode. It is not initialized in software standby mode. Same Trigger for TPC Output Groups 2 and 3: If TPC output groups 2 and 3 are triggered by the same compare match event, the NDRB address is H'FFA4. The upper 4 bits belong to group 3 and the lower 4 bits to group 2. Address H'FFA6 consists entirely of reserved bits that cannot be modified and are always read as 1. Address H'FFA4 Bit Initial value Read/Write 7 NDR15 0 R/W 6 NDR14 0 R/W 5 NDR13 0 R/W 4 NDR12 0 R/W 3 NDR11 0 R/W 2 NDR10 0 R/W 1 NDR9 0 R/W 0 NDR8 0 R/W Next data 15 to 12 These bits store the next output data for TPC output group 3 Next data 11 to 8 These bits store the next output data for TPC output group 2 Address H'FFA6 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Reserved bits Rev. 2.0, 03/01, page 409 of 822 Different Triggers for TPC Output Groups 2 and 3: If TPC output groups 2 and 3 are triggered by different compare match events, the address of the upper 4 bits of NDRB (group 3) is H'FFA4 and the address of the lower 4 bits (group 2) is H'FFA6. Bits 3 to 0 of address H'FFA4 and bits 7 to 4 of address H'FFA6 are reserved bits that cannot be modified and are always read as 1. Address H'FFA4 Bit Initial value Read/Write 7 NDR15 0 R/W 6 NDR14 0 R/W 5 NDR13 0 R/W 4 NDR12 0 R/W 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Next data 15 to 12 These bits store the next output data for TPC output group 3 Reserved bits Address H'FFA6 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 NDR11 0 R/W 2 NDR10 0 R/W 1 NDR9 0 R/W 0 NDR8 0 R/W Reserved bits Next data 11 to 8 These bits store the next output data for TPC output group 2 Rev. 2.0, 03/01, page 410 of 822 11.2.7 Next Data Enable Register A (NDERA) NDERA is an 8-bit readable/writable register that enables or disables TPC output groups 1 and 0 (TP7 to TP0) on a bit-by-bit basis. Bit Initial value Read/Write 7 NDER7 0 R/W 6 NDER6 0 R/W 5 NDER5 0 R/W 4 NDER4 0 R/W 3 NDER3 0 R/W 2 NDER2 0 R/W 1 NDER1 0 R/W 0 NDER0 0 R/W Next data enable 7 to 0 These bits enable or disable TPC output groups 1 and 0 If a bit is enabled for TPC output by NDERA, then when the ITU compare match event selected in the TPC output control register (TPCR) occurs, the NDRA value is automatically transferred to the corresponding PADR bit, updating the output value. If TPC output is disabled, the bit value is not transferred from NDRA to PADR and the output value does not change. NDERA is initialized to H'00 by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 0--Next Data Enable 7 to 0 (NDER7 to NDER0): These bits enable or disable TPC output groups 1 and 0 (TP7 to TP0) on a bit-by-bit basis. Bits 7 to 0: NDER7 to NDER0 0 1 Description TPC outputs TP7 to TP0 are disabled (NDR7 to NDR0 are not transferred to PA7 to PA0) TPC outputs TP7 to TP0 are enabled (NDR7 to NDR0 are transferred to PA7 to PA0) (Initial value) Rev. 2.0, 03/01, page 411 of 822 11.2.8 Next Data Enable Register B (NDERB) NDERB is an 8-bit readable/writable register that enables or disables TPC output groups 3 and 2 (TP15 to TP8) on a bit-by-bit basis. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 NDER8 0 R/W NDER15 NDER14 NDER13 NDER12 NDER11 NDER10 NDER9 Next data enable 15 to 8 These bits enable or disable TPC output groups 3 and 2 If a bit is enabled for TPC output by NDERB, then when the ITU compare match event selected in the TPC output control register (TPCR) occurs, the NDRB value is automatically transferred to the corresponding PBDR bit, updating the output value. If TPC output is disabled, the bit value is not transferred from NDRB to PBDR and the output value does not change. NDERB is initialized to H'00 by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 0--Next Data Enable 15 to 8 (NDER15 to NDER8): These bits enable or disable TPC output groups 3 and 2 (TP15 to TP8) on a bit-by-bit basis. Bits 7 to 0: NDER15 to NDER8 0 1 Description TPC outputs TP15 to TP8 are disabled (NDR15 to NDR8 are not transferred to PB7 to PB0) TPC outputs TP15 to TP8 are enabled (NDR15 to NDR8 are transferred to PB7 to PB0) (Initial value) Rev. 2.0, 03/01, page 412 of 822 11.2.9 TPC Output Control Register (TPCR) TPCR is an 8-bit readable/writable register that selects output trigger signals for TPC outputs on a group-by-group basis. Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W 2 1 R/W 1 1 R/W 0 1 R/W G3CMS1 G3CMS0 G2CMS1 G2CMS0 G1CMS1 G1CMS0 G0CMS1 G0CMS0 Group 3 compare match select 1 and 0 These bits select the compare match Group 2 compare event that triggers TPC output group 3 match select 1 and 0 These bits select (TP15 to TP12 ) the compare match event that triggers Group 1 compare TPC output group 2 match select 1 and 0 These bits select (TP11 to TP8 ) the compare match event that triggers Group 0 compare TPC output group 1 match select 1 and 0 These bits select (TP7 to TP4 ) the compare match event that triggers TPC output group 0 (TP3 to TP0 ) TPCR is initialized to H'FF by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 and 6--Group 3 Compare Match Select 1 and 0 (G3CMS1, G3CMS0): These bits select the compare match event that triggers TPC output group 3 (TP15 to TP12). Bit 7: G3CMS1 0 Bit 6: G3CMS0 0 1 1 0 1 Description TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 0 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 1 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 2 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 3 (Initial value) Rev. 2.0, 03/01, page 413 of 822 Bits 5 and 4--Group 2 Compare Match Select 1 and 0 (G2CMS1, G2CMS0): These bits select the compare match event that triggers TPC output group 2 (TP11 to TP8). Bit 5: G2CMS1 0 Bit 4: G2CMS0 0 1 1 0 1 Description TPC output group 2 (TP11 to TP8) is triggered by compare match in ITU channel 0 TPC output group 2 (TP11 to TP8) is triggered by compare match in ITU channel 1 TPC output group 2 (TP11 to TP8) is triggered by compare match in ITU channel 2 TPC output group 2 (TP11 to TP8) is triggered by compare match in ITU channel 3 (Initial value) Bits 3 and 2--Group 1 Compare Match Select 1 and 0 (G1CMS1, G1CMS0): These bits select the compare match event that triggers TPC output group 1 (TP7 to TP4). Bit 3: G1CMS1 0 Bit 2: G1CMS0 0 1 1 0 1 Description TPC output group 1 (TP7 to TP4) is triggered by compare match in ITU channel 0 TPC output group 1 (TP7 to TP4) is triggered by compare match in ITU channel 1 TPC output group 1 (TP7 to TP4) is triggered by compare match in ITU channel 2 TPC output group 1 (TP7 to TP4) is triggered by compare match in ITU channel 3 (Initial value) Bits 1 and 0--Group 0 Compare Match Select 1 and 0 (G0CMS1, G0CMS0): These bits select the compare match event that triggers TPC output group 0 (TP3 to TP0). Bit 1: G0CMS1 0 Bit 0: G0CMS0 0 1 1 0 1 Description TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 0 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 1 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 2 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 3 (Initial value) Rev. 2.0, 03/01, page 414 of 822 11.2.10 TPC Output Mode Register (TPMR) TPMR is an 8-bit readable/writable register that selects normal or non-overlapping TPC output for each group. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W G3NOV G2NOV G1NOV G0NOV Reserved bits Group 3 non-overlap Selects non-overlapping TPC output for group 3 (TP15 to TP12 ) Group 2 non-overlap Selects non-overlapping TPC output for group 2 (TP11 to TP8 ) Group 1 non-overlap Selects non-overlapping TPC output for group 1 (TP7 to TP4 ) Group 0 non-overlap Selects non-overlapping TPC output for group 0 (TP3 to TP0 ) The output trigger period of a non-overlapping TPC output waveform is set in general register B (GRB) in the ITU channel selected for output triggering. The non-overlap margin is set in general register A (GRA). The output values change at compare match A and B. For details see section 11.3.4, Non-Overlapping TPC Output. TPMR is initialized to H'F0 by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 4--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 415 of 822 Bit 3--Group 3 Non-Overlap (G3NOV): Selects normal or non-overlapping TPC output for group 3 (TP15 to TP12). Bit 3: G3NOV 0 1 Description Normal TPC output in group 3 (output values change at compare match A in the selected ITU channel) (Initial value) Non-overlapping TPC output in group 3 (independent 1 and 0 output at compare match A and B in the selected ITU channel) Bit 2--Group 2 Non-Overlap (G2NOV): Selects normal or non-overlapping TPC output for group 2 (TP11 to TP8). Bit 2: G2NOV 0 1 Description Normal TPC output in group 2 (output values change at compare match A in the selected ITU channel) (Initial value) Non-overlapping TPC output in group 2 (independent 1 and 0 output at compare match A and B in the selected ITU channel) Bit 1--Group 1 Non-Overlap (G1NOV): Selects normal or non-overlapping TPC output for group 1 (TP7 to TP4). Bit 1: G1NOV 0 1 Description Normal TPC output in group 1 (output values change at compare match A in the selected ITU channel) (Initial value) Non-overlapping TPC output in group 1 (independent 1 and 0 output at compare match A and B in the selected ITU channel) Bit 0--Group 0 Non-Overlap (G0NOV): Selects normal or non-overlapping TPC output for group 0 (TP3 to TP0). Bit 0: G0NOV 0 1 Description Normal TPC output in group 0 (output values change at compare match A in the selected ITU channel) (Initial value) Non-overlapping TPC output in group 0 (independent 1 and 0 output at compare match A and B in the selected ITU channel) Rev. 2.0, 03/01, page 416 of 822 11.3 11.3.1 Operation Overview When corresponding bits in PADDR or PBDDR and NDERA or NDERB are set to 1, TPC output is enabled. The TPC output initially consists of the corresponding PADR or PBDR contents. When a compare-match event selected in TPCR occurs, the corresponding NDRA or NDRB bit contents are transferred to PADR or PBDR to update the output values. Figure 11.2 illustrates the TPC output operation. Table 11.3 summarizes the TPC operating conditions. DDR Q NDER Q Output trigger signal C Q TPC output pin DR D Q NDR D Internal data bus Figure 11.2 TPC Output Operation Table 11.3 TPC Operating Conditions NDER 0 1 DDR 0 1 0 1 Pin Function Generic input port Generic output port Generic input port (but the DR bit is a read-only bit, and when compare match occurs, the NDR bit value is transferred to the DR bit) TPC pulse output Sequential output of up to 16-bit patterns is possible by writing new output data to NDRA and NDRB before the next compare match. For information on non-overlapping operation, see section 11.3.4, Non-Overlapping TPC Output. Rev. 2.0, 03/01, page 417 of 822 11.3.2 Output Timing If TPC output is enabled, NDRA/NDRB contents are transferred to PADR/PBDR and output when the selected compare match event occurs. Figure 11.3 shows the timing of these operations for the case of normal output in groups 2 and 3, triggered by compare match A. TCNT N N+1 GRA Compare match A signal N NDRB n PBDR TP8 to TP15 m m n n Figure 11.3 Timing of Transfer of Next Data Register Contents and Output (Example) Rev. 2.0, 03/01, page 418 of 822 11.3.3 Normal TPC Output Sample Setup Procedure for Normal TPC Output: Figure 11.4 shows a sample procedure for setting up normal TPC output. Normal TPC output 1. Set TIOR to make GRA an output compare register (with output inhibited). 1 2 3 4 2. Set the TPC output trigger period. 3. Select the counter clock source with bits TPSC2 to TPSC0 in TCR. Select the counter clear source with bits CCLR1 and CCLR0. 4. Enable the IMFA interrupt in TIER. The DMAC can also be set up to transfer data to the next data register. 5. Set the initial output values in the DR bits of the input/output port pins to be used for TPC output. 6. Set the DDR bits of the input/output port pins to be used for TPC output to 1. 7. Set the NDER bits of the pins to be used for TPC output to 1. 8. Select the ITU compare match event to be used as the TPC output trigger in TPCR. 9. Set the next TPC output values in the NDR bits. 10. Set the STR bit to 1 in TSTR to start the timer counter. 11. At each IMFA interrupt, set the next output values in the NDR bits. 11 Select GR functions Set GRA value ITU setup Select counting operation Select interrupt request Set initial output data Select port output Port and TPC setup Enable TPC output Select TPC output trigger Set next TPC output data 5 6 7 8 9 ITU setup Start counter 10 Compare match? Yes Set next TPC output value Set next TPC output data No Figure 11.4 Setup Procedure for Normal TPC Output (Example) Rev. 2.0, 03/01, page 419 of 822 Example of Normal TPC Output (Example of Five-Phase Pulse Output): Figure 11.5 shows an example in which the TPC is used for cyclic five-phase pulse output. TCNT value TCNT GRA Compare match H'0000 NDRB 80 C0 40 60 20 30 10 18 08 88 80 C0 40 Time PBDR 00 80 C0 40 60 20 30 10 18 08 88 80 C0 TP15 TP14 TP13 TP12 TP11 1. The ITU channel to be used as the output trigger channel is set up so that GRA is an output compare register and the counter will be cleared by compare match A. The trigger period is set in GRA. The IMIEA bit is set to 1 in TIER to enable the compare match A interrupt. 2. H'F8 is written in PBDDR and NDERB, and bits G3CMS1, G3CMS0, G2CMS1, and G2CMS0 are set in TPCR to select compare match in the ITU channel set up in step 1 as the output trigger. Output data H'80 is written in NDRB. 3. The timer counter in this ITU channel is started. When compare match A occurs, the NDRB contents are transferred to PBDR and output. The compare match/input capture A (IMFA) interrupt service routine writes the next output data (H'C0) in NDRB. 4. Five-phase overlapping pulse output (one or two phases active at a time) can be obtained by writing H'40, H'60, H'20, H'30, H'10, H'18, H'08, H'88... at successive IMFA interrupts. If the DMAC is set for activation by this interrupt, pulse output can be obtained without loading the CPU. Figure 11.5 Normal TPC Output Example (Five-Phase Pulse Output) Rev. 2.0, 03/01, page 420 of 822 11.3.4 Non-Overlapping TPC Output Sample Setup Procedure for Non-Overlapping TPC Output: Figure 11.6 shows a sample procedure for setting up non-overlapping TPC output. Non-overlapping TPC output 1. Set TIOR to make GRA and GRB output compare registers (with output inhibited). 1 2 3 4 2. Set the TPC output trigger period in GRB and the non-overlap margin in GRA. 3. Select the counter clock source with bits TPSC2 to TPSC0 in TCR. Select the counter clear source with bits CCLR1 and CCLR0. 4. Enable the IMFA interrupt in TIER. The DMAC can also be set up to transfer data to the next data register. 5. Set the initial output values in the DR bits of the input/output port pins to be used for TPC output. 6. Set the DDR bits of the input/output port pins to be used for TPC output to 1. 7. Set the NDER bits of the pins to be used for TPC output to 1. 8. In TPCR, select the ITU compare match event to be used as the TPC output trigger. 9. In TPMR, select the groups that will operate in non-overlap mode. 10. Set the next TPC output values in the NDR bits. 11. Set the STR bit to 1 in TSTR to start the timer counter. 12 12. At each IMFA interrupt, write the next output value in the NDR bits. Select GR functions Set GR values ITU setup Select counting operation Select interrupt requests Set initial output data Set up TPC output Enable TPC transfer Select TPC transfer trigger Select non-overlapping groups Set next TPC output data 5 6 7 8 9 10 11 Port and TPC setup ITU setup Start counter Compare match A? Yes Set next TPC output value No Figure 11.6 Setup Procedure for Non-Overlapping TPC Output (Example) Rev. 2.0, 03/01, page 421 of 822 Example of Non-Overlapping TPC Output (Example of Four-Phase Complementary NonOverlapping Output): Figure 11.7 shows an example of the use of TPC output for four-phase complementary non-overlapping pulse output. TCNT value GRB GRA H'0000 NDRB 95 65 59 56 95 65 Time TCNT PBDR 00 95 05 65 41 59 50 56 14 95 05 65 Non-overlap margin TP15 TP14 TP13 TP12 TP11 TP10 TP9 TP8 Figure 11.7 Non-Overlapping TPC Output Example (Four-Phase Complementary Non-Overlapping Pulse Output) This operation example is described below. * The output trigger ITU channel is set up so that GRA and GRB are output compare registers and the counter will be cleared by compare match B. The TPC output trigger period is set in GRB. The non-overlap margin is set in GRA. The IMIEA bit is set to 1 in TIER to enable IMFA interrupts. H'FF is written in PBDDR and NDERB, and bits G3CMS1, G3CMS0, G2CMS1, and G2CMS0 are set in TPCR to select compare match in the ITU channel set up in step 1 as the output trigger. Bits G3NOV and G2NOV are set to 1 in TPMR to select non-overlapping output. Output data H'95 is written in NDRB. * Rev. 2.0, 03/01, page 422 of 822 * The timer counter in this ITU channel is started. When compare match B occurs, outputs change from 1 to 0. When compare match A occurs, outputs change from 0 to 1 (the change from 0 to 1 is delayed by the value of GRA). The IMFA interrupt service routine writes the next output data (H'65) in NDRB. Four-phase complementary non-overlapping pulse output can be obtained by writing H'59, H'56, H'95... at successive IMFA interrupts. If the DMAC is set for activation by this interrupt, pulse output can be obtained without loading the CPU. TPC Output Triggering by Input Capture * 11.3.5 TPC output can be triggered by ITU input capture as well as by compare match. If GRA, and GRB functions as an input capture register in the ITU channel selected in TPCR, TPC output will be triggered by the input capture signal. Figure 11.8 shows the timing. TIOC pin Input capture signal NDR N DR M N Figure 11.8 TPC Output Triggering by Input Capture (Example) Rev. 2.0, 03/01, page 423 of 822 11.4 11.4.1 Usage Notes Operation of TPC Output Pins TP0 to TP15 are multiplexed with ITU, DMAC, address bus, and other pin functions. When ITU, DMAC, or address output is enabled, the corresponding pins cannot be used for TPC output. The data transfer from NDR bits to DR bits takes place, however, regardless of the usage of the pin. Pin functions should be changed only under conditions in which the output trigger event will not occur. 11.4.2 Note on Non-Overlapping Output During non-overlapping operation, the transfer of NDR bit values to DR bits takes place as follows. 1. NDR bits are always transferred to DR bits at compare match A. 2. At compare match B, NDR bits are transferred only if their value is 0. Bits are not transferred if their value is 1. Figure 11.9 illustrates the non-overlapping TPC output operation. DDR Q NDER Q Compare match A Compare match B C Q TPC output pin DR D Q NDR D Internal data bus Figure 11.9 Non-Overlapping TPC Output Rev. 2.0, 03/01, page 424 of 822 Therefore, 0 data can be transferred ahead of 1 data by making compare match B occur before compare match A. NDR contents should not be altered during the interval from compare match B to compare match A (the non-overlap margin). This can be accomplished by having the IMFA interrupt service routine write the next data in NDR, or by having the IMFA interrupt activate the DMAC. The next data must be written before the next compare match B occurs. Figure 11.10 shows the timing relationships. Compare match A Compare match B NDR write NDR write NDR DR 0 output 0/1 output Write to NDR in this interval Do not write to NDR in this interval Do not write to NDR in this interval 0 output 0/1 output Write to NDR in this interval Figure 11.10 Non-Overlapping Operation and NDR Write Timing Rev. 2.0, 03/01, page 425 of 822 Rev. 2.0, 03/01, page 426 of 822 Section 12 Watchdog Timer 12.1 Overview The H8/3052F has an on-chip watchdog timer (WDT). The WDT has two selectable functions: it can operate as a watchdog timer to supervise system operation, or it can operate as an interval timer. As a watchdog timer, it generates a reset signal for the chip if a system crash allows the timer counter (TCNT) to overflow before being rewritten. In interval timer operation, an interval timer interrupt is requested at each TCNT overflow. 12.1.1 Features WDT features are listed below. * Selection of eight counter clock sources /2, /32, /64, /128, /256, /512, /2048, or /4096 * Interval timer option * Timer counter overflow generates a reset signal or interrupt. The reset signal is generated in watchdog timer operation. An interval timer interrupt is generated in interval timer operation. * Watchdog timer reset signal resets the entire chip internally. The reset signal generated by timer counter overflow during watchdog timer operation resets the entire chip internally. With the H8/3052F, a reset signal cannot be output externally. Rev. 2.0, 03/01, page 427 of 822 12.1.2 Block Diagram Figure 12.1 shows a block diagram of the WDT. Overflow TCNT Interrupt signal Interrupt (interval timer) control TCSR Read/ write control Internal data bus RSTCSR Internal clock sources /2 /32 /64 Clock Clock selector /128 /256 /512 /2048 /4096 Reset (internal) Reset control Legend TCNT: Timer counter TCSR: Timer control/status register RSTCSR: Reset control/status register Figure 12.1 WDT Block Diagram 12.1.3 Register Configuration Table 12.1 summarizes the WDT registers. Table 12.1 WDT Registers 1 Address* Write* 2 Read H'FFA8 H'FFA9 H'FFAB Name Timer control/status register Timer counter Reset control/status register Abbreviation TCSR TCNT RSTCSR R/W R/(W)* R/W R/(W)* 3 3 Initial Value H'18 H'00 H'3F H'FFA8 H'FFAA Notes: 1. Lower 16 bits of the address. 2. Write word data starting at this address. 3. Only 0 can be written in bit 7, to clear the flag. Rev. 2.0, 03/01, page 428 of 822 12.2 12.2.1 Register Descriptions Timer Counter (TCNT) TCNT is an 8-bit readable and writable* up-counter. Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W When the TME bit is set to 1 in TCSR, TCNT starts counting pulses generated from an internal clock source selected by bits CKS2 to CKS0 in TCSR. When the count overflows (changes from H'FF to H'00), the OVF bit is set to 1 in TCSR. TCNT is initialized to H'00 by a reset and when the TME bit is cleared to 0. Note: * TCNT is write-protected by a password. For details see section 12.2.4, Notes on Register Access. Rev. 2.0, 03/01, page 429 of 822 12.2.2 Timer Control/Status Register (TCSR) 1 TCSR is an 8-bit readable and writable* register. Its functions include selecting the timer mode and clock source. Bit Initial value Read/Write 7 OVF 0 R/(W)*2 6 WT/ 0 R/W 5 TME 0 R/W 4 -- 1 -- 3 -- 1 -- 2 CKS2 0 R/W 1 CKS1 0 R/W 0 CKS0 0 R/W Clock select These bits select the TCNT clock source Reserved bits Timer enable Selects whether TCNT runs or halts Timer mode select Selects the mode Overflow flag Status flag indicating overflow Bits 7 to 5 are initialized to 0 by a reset and in standby mode. Bits 2 to 0 are initialized to 0 by a reset. In software standby mode bits 2 to 0 are not initialized, but retain their previous values. Notes: 1. TCSR differs from other registers in being more difficult to write. For details see section 12.2.4, Notes on Register Access. 2. Only 0 can be written, to clear the flag. Bit 7--Overflow Flag (OVF): This status flag indicates that the timer counter has overflowed from H'FF to H'00. Bit 7: OVF 0 1 Description [Clearing condition] Cleared by reading OVF when OVF = 1, then writing 0 in OVF [Setting condition] Set when TCNT changes from H'FF to H'00 (Initial value) Rev. 2.0, 03/01, page 430 of 822 Bit 6--Timer Mode Select (WT/,7 Selects whether to use the WDT as a watchdog timer or ,7): ,7 interval timer. If used as an interval timer, the WDT generates an interval timer interrupt request when TCNT overflows. If used as a watchdog timer, the WDT generates a reset signal when TCNT overflows. Bit 6: WT/,7 ,7 0 1 Description Interval timer: requests interval timer interrupts Watchdog timer: generates a reset signal (Initial value) Bit 5--Timer Enable (TME): Selects whether TCNT runs or is halted. When WT/,7 = 1, clear the SYSCR software standby bit (SSBY) to 0, then set the TME to 1. When SSBY is set to 1, clear TME to 0. Bit 5: TME 0 1 Description TCNT is initialized to H'00 and halted TCNT is counting and CPU interrupt requests are enabled (Initial value) Bits 4 and 3--Reserved: Read-only bits, always read as 1. Bits 2 to 0--Clock Select 2 to 0 (CKS2/1/0): These bits select one of eight internal clock sources, obtained by prescaling the system clock (), for input to TCNT. Bit 2: CKS2 0 Bit 1: CKS1 0 1 1 0 1 Bit 0: CKS0 0 1 0 1 0 1 0 1 Description /2 /32 /64 /128 /256 /512 /2048 /4096 (Initial value) Rev. 2.0, 03/01, page 431 of 822 12.2.3 Reset Control/Status Register (RSTCSR) 1 RSTCSR is an 8-bit readable/writable* register that monitors the state of the reset signal generated by watchdog timer overflow. Bit Initial value Read/Write 7 WRST 0 R/(W)*2 6 -- 0 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Reserved bits Reserved bit Must not be set to 1*3 Watchdog timer reset Indicates that a reset signal has been generated Bit 7 is initialized by input of a reset signal at the 5(6 pin. It is not initialized by reset signals generated by watchdog timer overflow. Notes: 1. RSTCSR differs from other registers in being more difficult to write. For details see section 12.2.4, Notes on Register Access. 2. Only 0 can be written in bit 7, to clear the flag. 3. Do not set bit 6 to 1. Bit 7--Watchdog Timer Reset (WRST): During watchdog timer operation, this bit indicates that TCNT has overflowed and generated a reset signal. This reset signal resets the entire chip internally. Bit 7: WRST 0 Description [Clearing conditions] Cleared to 0 by reset signal input at 5(6 pin 1 [Setting condition] Set when TCNT overflow generates a reset signal during watchdog timer operation (Initial value) Cleared by reading WRST when WRST = 1, then writing 0 in WRST Bit 6--Reserved: Do not set to 1. Bits 5 to 0--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 432 of 822 12.2.4 Notes on Register Access The watchdog timer's TCNT, TCSR, and RSTCSR registers differ from other registers in being more difficult to write. The procedures for writing and reading these registers are given below. Writing to TCNT and TCSR: These registers must be written by a word transfer instruction. They cannot be written by byte instructions. Figure 12.2 shows the format of data written to TCNT and TCSR. TCNT and TCSR both have the same write address. The write data must be contained in the lower byte of the written word. The upper byte must contain H'5A (password for TCNT) or H'A5 (password for TCSR). This transfers the write data from the lower byte to TCNT or TCSR. TCNT write Address H'FFA8* 15 H'5A 87 Write data 0 TCSR write Address H'FFA8* 15 H'A5 87 Write data 0 Note: * Lower 16 bits of the address. Figure 12.2 Format of Data Written to TCNT and TCSR Writing to RSTCSR: RSTCSR must be written by a word transfer instruction. It cannot be written by byte transfer instructions. Figure 12.3 shows the format of data written to RSTCSR. To write 0 in the WRST bit, the write data must have H'A5 in the upper byte and H'00 in the lower byte. The H'00 in the lower byte clears the WRST bit in RSTCSR to 0. Writing 0 in WRST bit Address H'FFAA* 15 H'A5 87 H'00 0 Note: * Lower 16 bits of the address. Figure 12.3 Format of Data Written to RSTCSR Reading TCNT, TCSR, and RSTCSR: These registers are read like other registers. Byte access instructions can be used. The read addresses are H'FFA8 for TCSR, H'FFA9 for TCNT, and H'FFAB for RSTCSR, as listed in table 12.2. Rev. 2.0, 03/01, page 433 of 822 Table 12.2 Read Addresses of TCNT, TCSR, and RSTCSR Address* H'FFA8 H'FFA9 H'FFAB Register TCSR TCNT RSTCSR Note: * Lower 16 bits of the address. 12.3 Operation Operations when the WDT is used as a watchdog timer and as an interval timer are described below. 12.3.1 Watchdog Timer Operation Figure 12.4 illustrates watchdog timer operation. To use the WDT as a watchdog timer, set the WT/,7 and TME bits to 1 in TCSR. Software must prevent TCNT overflow by rewriting the TCNT value (normally by writing H'00) before overflow occurs. If TCNT fails to be rewritten and overflows due to a system crash etc., the chip is internally reset for a duration of 518 states. A reset generated by the WDT has the same vector as a reset generated by input at the 5(6 pin. Software can distinguish a 5(6 reset from a watchdog reset by checking the WRST bit in RSTCSR. If a 5(6 reset and a watchdog reset occur simultaneously, the 5(6 reset takes priority. H'FF TCNT count value H'00 WDT overflow TME set to 1 OVF = 1 Start Internal reset signal H'00 written in TCNT Reset H'00 written in TCNT 518 states Figure 12.4 Watchdog Timer Operation Rev. 2.0, 03/01, page 434 of 822 12.3.2 Interval Timer Operation Figure 12.5 illustrates interval timer operation. To use the WDT as an interval timer, clear bit WT/,7 to 0 and set bit TME to 1 in TCSR. An interval timer interrupt request is generated at each TCNT overflow. This function can be used to generate interval timer interrupts at regular intervals. H'FF TCNT count value Time t H'00 WT/ = 0 TME = 1 Interval timer interrupt Interval timer interrupt Interval timer interrupt Interval timer interrupt Figure 12.5 Interval Timer Operation 12.3.3 Timing of Setting of Overflow Flag (OVF) Figure 12.6 shows the timing of setting of the OVF flag in TCSR. The OVF flag is set to 1 when TCNT overflows. At the same time, a reset signal is generated in watchdog timer operation, or an interval timer interrupt is generated in interval timer operation. TCNT H'FF H'00 Overflow signal OVF Figure 12.6 Timing of Setting of OVF Rev. 2.0, 03/01, page 435 of 822 12.3.4 Timing of Setting of Watchdog Timer Reset Bit (WRST) The WRST bit in RSTCSR is valid when bits WT/,7 and TME are both set to 1 in TCSR. Figure 12.7 shows the timing of setting of WRST and the internal reset timing. The WRST bit is set to 1 when TCNT overflows and OVF is set to 1. At the same time an internal reset signal is generated for the entire chip. This internal reset signal clears OVF to 0, but the WRST bit remains set to 1. The reset routine must therefore clear the WRST bit. TCNT H'FF H'00 Overflow signal OVF WDT internal reset WRST Figure 12.7 Timing of Setting of WRST Bit and Internal Reset Rev. 2.0, 03/01, page 436 of 822 12.4 Interrupts During interval timer operation, an overflow generates an interval timer interrupt (WOVI). The interval timer interrupt is requested whenever the OVF bit is set to 1 in TCSR. 12.5 Usage Notes Contention between TCNT Write and Increment: If a timer counter clock pulse is generated during the T3 state of a write cycle to TCNT, the write takes priority and the timer count is not incremented. See figure 12.8. Write cycle: CPU writes to TCNT T1 T2 T3 TCNT Internal write signal TCNT input clock TCNT N M Counter write data Figure 12.8 Contention between TCNT Write and Increment Changing CKS2 to CKS0 Values: Halt TCNT by clearing the TME bit to 0 in TCSR before changing the values of bits CKS2 to CKS0. Rev. 2.0, 03/01, page 437 of 822 Rev. 2.0, 03/01, page 438 of 822 Section 13 Serial Communication Interface 13.1 Overview The H8/3052F has a serial communication interface (SCI) with two independent channels. The two channels are functionally identical. The SCI can communicate in asynchronous or synchronous mode. It also has a multiprocessor communication function for serial communication among two or more processors. When the SCI is not used, it can be halted to conserve power. Each SCI channel can be halted independently. For details see section 20.6, Module Standby Function. Channel 0 (SCI0) also has a smart card interface function conforming to the ISO/IEC7816-3 (Identification Card) standard. This function supports serial communication with a smart card. For details, see section 14, Smart Card Interface. 13.1.1 Features SCI features are listed below. * Selection of asynchronous or synchronous mode for serial communication Asynchronous mode Serial data communication is synchronized one character at a time. The SCI can communicate with a universal asynchronous receiver/transmitter (UART), asynchronous communication interface adapter (ACIA), or other chip that employs standard asynchronous serial communication. It can also communicate with two or more other processors using the multiprocessor communication function. There are twelve selectable serial data communication formats. * Data length: 7 or 8 bits * Stop bit length: 1 or 2 bits * Parity bit: even, odd, or none * Multiprocessor bit: 1 or 0 * Receive error detection: parity, overrun, and framing errors * Break detection: by reading the RxD level directly when a framing error occurs Synchronous mode Serial data communication is synchronized with a clock signal. The SCI can communicate with other chips having a synchronous communication function. There is one serial data communication format. * Data length: 8 bits * Receive error detection: overrun errors Rev. 2.0, 03/01, page 439 of 822 * Full duplex communication The transmitting and receiving sections are independent, so the SCI can transmit and receive simultaneously. The transmitting and receiving sections are both double-buffered, so serial data can be transmitted and received continuously. * Built-in baud rate generator with selectable bit rates * Selectable transmit/receive clock sources: internal clock from baud rate generator, or external clock from the SCK pin. * Four types of interrupts Transmit-data-empty, transmit-end, receive-data-full, and receive-error interrupts are requested independently. The transmit-data-empty and receive-data-full interrupts from SCI0 can activate the DMA controller (DMAC) to transfer data. Rev. 2.0, 03/01, page 440 of 822 13.1.2 Block Diagram Figure 13.1 shows a block diagram of the SCI. Bus interface Internal data bus Module data bus RDR RxD RSR TDR TSR SSR SCR SMR Transmit/ receive control BRR Baud rate generator Clock External clock TEI TXI RXI ERI /4 /16 /64 TxD Parity generate Parity check SCK Legend RSR: Receive shift register RDR: Receive data register TSR: Transmit shift register TDR: Transmit data register SMR: Serial mode register SCR: Serial control register SSR: Serial status register BRR: Bit rate register Figure 13.1 SCI Block Diagram Rev. 2.0, 03/01, page 441 of 822 13.1.3 Pin Configuration The SCI has serial pins for each channel as listed in table 13.1. Table 13.1 SCI Pins Channel 0 Name Serial clock pin Receive data pin Transmit data pin 1 Serial clock pin Receive data pin Transmit data pin Abbreviation SCK0 RxD0 TxD0 SCK1 RxD1 TxD1 I/O Input/output Input Output Input/output Input Output Function SCI0 clock input/output SCI0 receive data input SCI0 transmit data output SCI1 clock input/output SCI1 receive data input SCI1 transmit data output 13.1.4 Register Configuration The SCI has internal registers as listed in table 13.2. These registers select asynchronous or synchronous mode, specify the data format and bit rate, and control the transmitter and receiver sections. Table 13.2 Registers Channel 0 Address* H'FFB0 H'FFB1 H'FFB2 H'FFB3 H'FFB4 H'FFB5 1 H'FFB8 H'FFB9 H'FFBA H'FFBB H'FFBC H'FFBD 1 Name Serial mode register Bit rate register Serial control register Transmit data register Serial status register Receive data register Serial mode register Bit rate register Serial control register Transmit data register Serial status register Receive data register Abbreviation SMR BRR SCR TDR SSR RDR SMR BRR SCR TDR SSR RDR R/W R/W R/W R/W R/W R/(W) * R R/W R/W R/W R/W R/(W)*2 R 2 Initial Value H'00 H'FF H'00 H'FF H'84 H'00 H'00 H'FF H'00 H'FF H'84 H'00 Notes: 1. Lower 16 bits of the address. 2. Only 0 can be written, to clear flags. Rev. 2.0, 03/01, page 442 of 822 13.2 13.2.1 Register Descriptions Receive Shift Register (RSR) RSR is the register that receives serial data. Bit 7 6 5 4 3 2 1 0 Read/Write -- -- -- -- -- -- -- -- The SCI loads serial data input at the RxD pin into RSR in the order received, LSB (bit 0) first, thereby converting the data to parallel data. When 1 byte has been received, it is automatically transferred to RDR. The CPU cannot read or write RSR directly. 13.2.2 Receive Data Register (RDR) RDR is the register that stores received serial data. Bit Initial value Read/Write 7 0 R 6 0 R 5 0 R 4 0 R 3 0 R 2 0 R 1 0 R 0 0 R When the SCI finishes receiving 1 byte of serial data, it transfers the received data from RSR into RDR for storage. RSR is then ready to receive the next data. This double buffering allows data to be received continuously. RDR is a read-only register. Its contents cannot be modified by the CPU. RDR is initialized to H'00 by a reset and in standby mode. Rev. 2.0, 03/01, page 443 of 822 13.2.3 Transmit Shift Register (TSR) TSR is the register that transmits serial data. Bit 7 6 5 4 3 2 1 0 Read/Write -- -- -- -- -- -- -- -- The SCI loads transmit data from TDR into TSR, then transmits the data serially from the TxD pin, LSB (bit 0) first. After transmitting one data byte, the SCI automatically loads the next transmit data from TDR into TSR and starts transmitting it. If the TDRE flag is set to 1 in SSR, however, the SCI does not load the TDR contents into TSR. The CPU cannot read or write TSR directly. 13.2.4 Transmit Data Register (TDR) TDR is an 8-bit register that stores data for serial transmission. Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W 2 1 R/W 1 1 R/W 0 1 R/W When the SCI detects that TSR is empty, it moves transmit data written in TDR from TDR into TSR and starts serial transmission. Continuous serial transmission is possible by writing the next transmit data in TDR during serial transmission from TSR. The CPU can always read and write TDR. TDR is initialized to H'FF by a reset and in standby mode. Rev. 2.0, 03/01, page 444 of 822 13.2.5 Serial Mode Register (SMR) SMR is an 8-bit register that specifies the SCI serial communication format and selects the clock source for the baud rate generator. Bit Initial value Read/Write 7 C/A 0 R/W 6 CHR 0 R/W 5 PE 0 R/W 4 O/E 0 R/W 3 STOP 0 R/W 2 MP 0 R/W 1 CKS1 0 R/W 0 CKS0 0 R/W Clock select 1/0 These bits select the baud rate generator's clock source Multiprocessor mode Selects the multiprocessor function Stop bit length Selects the stop bit length Parity mode Selects even or odd parity Parity enable Selects whether a parity bit is added Character length Selects character length in asynchronous mode Communication mode Selects asynchronous or synchronous mode The CPU can always read and write SMR. SMR is initialized to H'00 by a reset and in standby mode. Bit 7--Communication Mode (C/$): Selects whether the SCI operates in asynchronous or $ synchronous mode. Bit 7: C/$ $ 0 1 Description Asynchronous mode Synchronous mode (Initial value) Rev. 2.0, 03/01, page 445 of 822 Bit 6--Character Length (CHR): Selects 7-bit or 8-bit data length in asynchronous mode. In synchronous mode the data length is 8 bits regardless of the CHR setting. Bit 6: CHR 0 1 Description 8-bit data 7-bit data* (Initial value) Note: * When 7-bit data is selected, the MSB (bit 7) in TDR is not transmitted. Bit 5--Parity Enable (PE): In asynchronous mode, this bit enables or disables the addition of a parity bit to transmit data, and the checking of the parity bit in receive data. In synchronous mode the parity bit is neither added nor checked, regardless of the PE setting. Bit 5: PE 0 1 Description Parity bit not added or checked Parity bit added and checked* (Initial value) Note: * When PE is set to 1, an even or odd parity bit is added to transmit data according to the even or odd parity mode selected by the O/( bit, and the parity bit in receive data is checked to see that it matches the even or odd mode selected by the O/( bit. Bit 4--Parity Mode (O/(): Selects even or odd parity. The O/( bit setting is valid in ( asynchronous mode when the PE bit is set to 1 to enable the adding and checking of a parity bit. The O/( setting is ignored in synchronous mode, or when parity adding and checking is disabled in asynchronous mode. Bit 4: O/( ( 0 1 Description Even parity* Odd parity* 2 1 (Initial value) Notes: 1. When even parity is selected, the parity bit added to transmit data makes an even number of 1s in the transmitted character and parity bit combined. Receive data must have an even number of 1s in the received character and parity bit combined. 2. When odd parity is selected, the parity bit added to transmit data makes an odd number of 1s in the transmitted character and parity bit combined. Receive data must have an odd number of 1s in the received character and parity bit combined. Rev. 2.0, 03/01, page 446 of 822 Bit 3--Stop Bit Length (STOP): Selects one or two stop bits in asynchronous mode. This setting is used only in asynchronous mode. In synchronous mode no stop bit is added, so the STOP bit setting is ignored. Bit 3: STOP 0 1 Description One stop bit* 1 (Initial value) 2 Two stop bits* Notes: 1. One stop bit (with value 1) is added at the end of each transmitted character. 2. Two stop bits (with value 1) are added at the end of each transmitted character. In receiving, only the first stop bit is checked, regardless of the STOP bit setting. If the second stop bit is 1 it is treated as a stop bit. If the second stop bit is 0 it is treated as the start bit of the next incoming character. Bit 2--Multiprocessor Mode (MP): Selects a multiprocessor format. When a multiprocessor format is selected, parity settings made by the PE and O/( bits are ignored. The MP bit setting is valid only in asynchronous mode. It is ignored in synchronous mode. For further information on the multiprocessor communication function, see section 13.3.3, Multiprocessor Communication. Bit 2: MP 0 1 Description Multiprocessor function disabled Multiprocessor format selected (Initial value) Bits 1 and 0--Clock Select 1 and 0 (CKS1/0): These bits select the clock source of the on-chip baud rate generator. Four clock sources are available: , /4, /16, and /64. For the relationship between the clock source, bit rate register setting, and baud rate, see section 13.2.8, Bit Rate Register (BRR). Bit 1: CKS1 0 1 Bit 0: CKS0 0 1 0 1 Description /4 /16 /64 (Initial value) Rev. 2.0, 03/01, page 447 of 822 13.2.6 Serial Control Register (SCR) SCR enables the SCI transmitter and receiver, enables or disables serial clock output in asynchronous mode, enables or disables interrupts, and selects the transmit/receive clock source. Bit Initial value Read/Write 7 TIE 0 R/W 6 RIE 0 R/W 5 TE 0 R/W 4 RE 0 R/W 3 MPIE 0 R/W 2 TEIE 0 R/W 1 CKE1 0 R/W 0 CKE0 0 R/W Clock enable 1/0 These bits select the SCI clock source Transmit-end interrupt enable Enables or disables transmitend interrupts (TEI) Multiprocessor interrupt enable Enables or disables multiprocessor interrupts Receive enable Enables or disables the receiver Transmit enable Enables or disables the transmitter Receive interrupt enable Enables or disables receive-data-full interrupts (RXI) and receive-error interrupts (ERI) Transmit interrupt enable Enables or disables transmit-data-empty interrupts (TXI) The CPU can always read and write SCR. SCR is initialized to H'00 by a reset and in standby mode. Rev. 2.0, 03/01, page 448 of 822 Bit 7--Transmit Interrupt Enable (TIE): Enables or disables the transmit-data-empty interrupt (TXI) requested when the TDRE flag in SSR is set to 1 due to transfer of serial transmit data from TDR to TSR. Bit 7: TIE 0 1 Description Transmit-data-empty interrupt request (TXI) is disabled* Transmit-data-empty interrupt request (TXI) is enabled (Initial value) Note: * TXI interrupt requests can be cleared by reading the value 1 from the TDRE flag, then clearing it to 0; or by clearing the TIE bit to 0. Bit 6--Receive Interrupt Enable (RIE): Enables or disables the receive-data-full interrupt (RXI) requested when the RDRF flag is set to 1 in SSR due to transfer of serial receive data from RSR to RDR; also enables or disables the receive-error interrupt (ERI). Bit 6: RIE 0 1 Description Receive-data-full (RXI) and receive-error (ERI) interrupt requests are disabled* (Initial value) Receive-data-full (RXI) and receive-error (ERI) interrupt requests are enabled Note: * RXI and ERI interrupt requests can be cleared by reading the value 1 from the RDRF, FER, PER, or ORER flag, then clearing it to 0; or by clearing the RIE bit to 0. Bit 5--Transmit Enable (TE): Enables or disables the start of SCI serial transmitting operations. Bit 5: TE 0 1 Description 1 Transmitting disabled* (Initial value) Transmitting enabled* 2 Notes: 1. The TDRE bit is locked at 1 in SSR. 2. In the enabled state, serial transmitting starts when the TDRE bit in SSR is cleared to 0 after writing of transmit data into TDR. Select the transmit format in SMR before setting the TE bit to 1. Bit 4--Receive Enable (RE): Enables or disables the start of SCI serial receiving operations. Bit 4: RE 0 1 Description Receiving disabled* Receiving enabled* 1 (Initial value) 2 Notes: 1. Clearing the RE bit to 0 does not affect the RDRF, FER, PER, and ORER flags. These flags retain their previous values. 2. In the enabled state, serial receiving starts when a start bit is detected in asynchronous mode, or serial clock input is detected in synchronous mode. Select the receive format in SMR before setting the RE bit to 1. Rev. 2.0, 03/01, page 449 of 822 Bit 3--Multiprocessor Interrupt Enable (MPIE): Enables or disables multiprocessor interrupts. The MPIE setting is valid only in asynchronous mode, and only if the MP bit is set to 1 in SMR. The MPIE setting is ignored in synchronous mode or when the MP bit is cleared to 0. Bit 3: MPIE 0 Description Multiprocessor interrupts are disabled (normal receive operation) (Initial value) [Clearing conditions] The MPIE bit is cleared to 0. MPB = 1 in received data. 1 Multiprocessor interrupts are enabled* Receive-data-full interrupts (RXI), receive-error interrupts (ERI), and setting of the RDRF, FER, and ORER status flags in SSR are disabled until data with the multiprocessor bit set to 1 is received. Note: * The SCI does not transfer receive data from RSR to RDR, does not detect receive errors, and does not set the RDRF, FER, and ORER flags in SSR. When it receives data in which MPB = 1, the SCI sets the MPB bit to 1 in SSR, automatically clears the MPIE bit to 0, enables RXI and ERI interrupts (if the RIE bit is set to 1 in SCR), and allows the FER and ORER flags to be set. Bit 2--Transmit-End Interrupt Enable (TEIE): Enables or disables the transmit-end interrupt (TEI) requested if TDR does not contain new transmit data when the MSB is transmitted. Bit 2: TEIE 0 1 Description Transmit-end interrupt requests (TEI) are disabled* Transmit-end interrupt requests (TEI) are enabled* (Initial value) Note: * TEI interrupt requests can be cleared by reading the value 1 from the TDRE flag in SSR, then clearing the TDRE flag to 0, thereby also clearing the TEND flag to 0; or by clearing the TEIE bit to 0. Rev. 2.0, 03/01, page 450 of 822 Bits 1 and 0--Clock Enable 1 and 0 (CKE1/0): These bits select the SCI clock source and enable or disable clock output from the SCK pin. Depending on the settings of CKE1 and CKE0, the SCK pin can be used for generic input/output, serial clock output, or serial clock input. The CKE0 setting is valid only in asynchronous mode, and only when the SCI is internally clocked (CKE1 = 0). The CKE0 setting is ignored in synchronous mode, or when an external clock source is selected (CKE1 = 1). Select the SCI operating mode in SMR before setting the CKE1 and CKE0 bits. For further details on selection of the SCI clock source, see table 13.9 in section 13.3, Operation. Bit 1: CKE1 0 Bit 0: CKE0 0 Description Asynchronous mode Synchronous mode Internal clock, SCK pin available for generic 1 input/output * Internal clock, SCK pin used for serial clock output * Internal clock, SCK pin used for clock output* External clock, SCK pin used for clock input * External clock, SCK pin used for clock input * 2 1 1 1 0 1 Asynchronous mode Synchronous mode Asynchronous mode Synchronous mode Asynchronous mode Synchronous mode Internal clock, SCK pin used for serial clock output 3 External clock, SCK pin used for serial clock input 3 External clock, SCK pin used for serial clock input Notes: 1. Initial value 2. The output clock frequency is the same as the bit rate. 3. The input clock frequency is 16 times the bit rate. Rev. 2.0, 03/01, page 451 of 822 13.2.7 Serial Status Register (SSR) SSR is an 8-bit register containing multiprocessor bit values, and status flags that indicate SCI operating status. Bit Initial value Read/Write 7 TDRE 1 R/(W)* 6 RDRF 0 R/(W)* 5 ORER 0 R/(W)* 4 FER 0 R/(W)* 3 PER 0 R/(W)* 2 TEND 1 R 1 MPB 0 R 0 MPBT 0 R/W Multiprocessor bit transfer Value of multiprocessor bit to be transmitted Multiprocessor bit Stores the received multiprocessor bit value Transmit end Status flag indicating end of transmission Parity error Status flag indicating detection of a receive parity error Framing error Status flag indicating detection of a receive framing error Overrun error Status flag indicating detection of a receive overrun error Receive data register full Status flag indicating that data has been received and stored in RDR Transmit data register empty Status flag indicating that transmit data has been transferred from TDR into TSR and new data can be written in TDR Note: * Only 0 can be written, to clear the flag. The CPU can always read and write SSR, but cannot write 1 in the TDRE, RDRF, ORER, PER, and FER flags. These flags can be cleared to 0 only if they have first been read while set to 1. The TEND and MPB flags are read-only bits that cannot be written. SSR is initialized to H'84 by a reset and in standby mode. Rev. 2.0, 03/01, page 452 of 822 Bit 7--Transmit Data Register Empty (TDRE): Indicates that the SCI has loaded transmit data from TDR into TSR and the next serial transmit data can be written in TDR. Bit 7: TDRE 0 Description TDR contains valid transmit data [Clearing conditions] Software reads TDRE while it is set to 1, then writes 0. The DMAC writes data in TDR. 1 TDR does not contain valid transmit data [Setting conditions] The chip is reset or enters standby mode. The TE bit in SCR is cleared to 0. TDR contents are loaded into TSR, so new data can be written in TDR. (Initial value) Bit 6--Receive Data Register Full (RDRF): Indicates that RDR contains new receive data. Bit 6: RDRF 0 Description RDR does not contain new receive data [Clearing conditions] The chip is reset or enters standby mode. Software reads RDRF while it is set to 1, then writes 0. The DMAC reads data from RDR. 1 RDR contains new receive data [Setting condition] When serial data is received normally and transferred from RSR to RDR. Note: The RDR contents and RDRF flag are not affected by detection of receive errors or by clearing of the RE bit to 0 in SCR. They retain their previous values. If the RDRF flag is still set to 1 when reception of the next data ends, an overrun error occurs and receive data is lost. (Initial value) Rev. 2.0, 03/01, page 453 of 822 Bit 5--Overrun Error (ORER): Indicates that data reception ended abnormally due to an overrun error. Bit 5: ORER 0 Description Receiving is in progress or has ended normally [Clearing conditions] The chip is reset or enters standby mode. Software reads ORER while it is set to 1, then writes 0. 1 2 A receive overrun error occurred* 1 (Initial value)* [Setting condition] Reception of the next serial data ends when RDRF = 1. Notes: 1. Clearing the RE bit to 0 in SCR does not affect the ORER flag, which retains its previous value. 2. RDR continues to hold the receive data before the overrun error, so subsequent receive data is lost. Serial receiving cannot continue while the ORER flag is set to 1. In synchronous mode, serial transmitting is also disabled. Bit 4--Framing Error (FER): Indicates that data reception ended abnormally due to a framing error in asynchronous mode. Bit 4: FER 0 Description Receiving is in progress or has ended normally [Clearing conditions] The chip is reset or enters standby mode. Software reads FER while it is set to 1, then writes 0. 1 2 A receive framing error occurred* 1 (Initial value)* [Setting condition] The stop bit at the end of receive data is checked and found to be 0. Notes: 1. Clearing the RE bit to 0 in SCR does not affect the FER flag, which retains its previous value. 2. When the stop bit length is 2 bits, only the first bit is checked. The second stop bit is not checked. When a framing error occurs the SCI transfers the receive data into RDR but does not set the RDRF flag. Serial receiving cannot continue while the FER flag is set to 1. In synchronous mode, serial transmitting is also disabled. Rev. 2.0, 03/01, page 454 of 822 Bit 3--Parity Error (PER): Indicates that data reception ended abnormally due to a parity error in asynchronous mode. Bit 3: PER 0 Description Receiving is in progress or has ended normally * [Clearing conditions] The chip is reset or enters standby mode. Software reads PER while it is set to 1, then writes 0. 1 A receive parity error occurred* [Setting condition] The number of 1s in receive data, including the parity bit, does not match the even or odd parity setting of O/E in SMR. Notes: 1. Clearing the RE bit to 0 in SCR does not affect the PER flag, which retains its previous value. 2. When a parity error occurs the SCI transfers the receive data into RDR but does not set the RDRF flag. Serial receiving cannot continue while the PER flag is set to 1. In synchronous mode, serial transmitting is also disabled. 2 1 (Initial value) Bit 2--Transmit End (TEND): Indicates that when the last bit of a serial character was transmitted TDR did not contain new transmit data, so transmission has ended. The TEND flag is a read-only bit and cannot be written. Bit 2: TEND 0 Description Transmission is in progress [Clearing conditions] Software reads TDRE while it is set to 1, then writes 0 in the TDRE flag. The DMAC writes data in TDR. 1 End of transmission [Setting conditions] The chip is reset or enters standby mode. The TE bit is cleared to 0 in SCR. TDRE is 1 when the last bit of a serial character is transmitted. (Initial value) Rev. 2.0, 03/01, page 455 of 822 Bit 1--Multiprocessor Bit (MPB): Stores the value of the multiprocessor bit in receive data when a multiprocessor format is used in asynchronous mode. MPB is a read-only bit and cannot be written. Bit 1: MPB 0 1 Description Multiprocessor bit value in receive data is 0* Multiprocessor bit value in receive data is 1 (Initial value) Note: * If the RE bit is cleared to 0 when a multiprocessor format is selected, MPB retains its previous value. Bit 0--Multiprocessor Bit Transfer (MPBT): Stores the value of the multiprocessor bit added to transmit data when a multiprocessor format is selected for transmitting in asynchronous mode. The MPBT setting is ignored in synchronous mode, when a multiprocessor format is not selected, or when the SCI is not transmitting. Bit 0: MPBT 0 1 Description Multiprocessor bit value in transmit data is 0 Multiprocessor bit value in transmit data is 1 (Initial value) 13.2.8 Bit Rate Register (BRR) BRR is an 8-bit register that, together with the CKS1 and CKS0 bits in SMR that select the baud rate generator clock source, determines the serial communication bit rate. Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W 2 1 R/W 1 1 R/W 0 1 R/W The CPU can always read and write BRR. BRR is initialized to H'FF by a reset and in standby mode. The two SCI channels have independent baud rate generator control, so different values can be set in the two channels. Table 13.3 shows examples of BRR settings in asynchronous mode. Table 13.4 shows examples of BRR settings in synchronous mode. Rev. 2.0, 03/01, page 456 of 822 Table 13.3 Examples of Bit Rates and BRR Settings in Asynchronous Mode (MHz) 2 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 1 1 0 0 0 0 0 0 0 0 0 N 141 103 207 103 51 25 12 6 2 1 1 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 -6.99 8.51 0 -18.62 n 1 1 0 0 0 0 0 0 0 0 0 2.097152 N 148 108 217 108 54 26 13 6 2 1 1 Error (%) -0.04 0.21 0.21 0.21 -0.70 1.14 -2.48 -2.48 13.78 4.86 -14.67 n 1 1 0 0 0 0 0 0 0 0 0 2.4576 N 174 127 255 127 63 31 15 7 3 1 1 Error (%) -0.26 0 0 0 0 0 0 0 0 22.88 0 n 1 1 1 0 0 0 0 0 0 0 -- N 212 155 77 155 77 38 19 9 4 2 -- 3 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 -2.34 -2.34 -2.34 0 -- (MHz) 3.6864 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 1 1 0 0 0 0 0 0 -- 0 N 64 191 95 191 95 47 23 11 5 -- 2 Error (%) 0.70 0 0 0 0 0 0 0 0 -- 0 n 2 1 1 0 0 0 0 0 0 0 0 N 70 207 103 207 103 51 25 12 6 3 2 4 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 -6.99 0 8.51 n 2 1 1 0 0 0 0 0 0 0 0 4.9152 N 86 255 127 255 127 63 31 15 7 4 3 Error (%) 0.31 0 0 0 0 0 0 0 0 -1.70 0 n 2 2 1 1 0 0 0 0 0 0 0 N 88 64 129 64 129 64 32 15 7 4 3 5 Error (%) -0.25 0.16 0.16 0.16 0.16 0.16 -1.36 1.73 1.73 0 1.73 Rev. 2.0, 03/01, page 457 of 822  (MHz) 6 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 2 1 1 0 0 0 0 0 0 0 N 106 77 155 77 155 77 38 19 9 5 4 Error (%) -0.44 0.16 0.16 0.16 0.16 0.16 0.16 -2.34 -2.34 0 -2.34 n 2 2 1 1 0 0 0 0 0 0 0 N 108 79 159 79 159 79 39 19 9 5 4 6.144 Error (%) 0.08 0 0 0 0 0 0 0 0 2.40 0 n 2 2 1 1 0 0 0 0 0 0 0 (MHz) 9.8304 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 2 1 1 0 0 0 0 0 0 0 N 174 127 255 127 255 127 63 31 15 9 7 Error (%) -0.26 0 0 0 0 0 0 0 0 -1.70 0 n 2 2 2 1 1 0 0 0 0 0 0 N 177 129 64 129 64 129 64 32 15 9 7 10 Error (%) -0.25 0.16 0.16 0.16 0.16 0.16 0.16 -1.36 1.73 0 1.73 n 2 2 2 1 1 0 0 0 0 0 0 N 212 155 77 155 77 155 77 38 19 11 9 12 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 -2.34 0 -2.34 n 2 2 2 1 1 0 0 0 0 0 0 12.288 N 217 159 79 159 79 159 79 39 19 11 9 Error (%) 0.08 0 0 0 0 0 0 0 0 2.40 0 7.3728 N 130 95 191 95 191 95 47 23 11 6 5 Error (%) -0.07 0 0 0 0 0 0 0 0 5.33 0 n 2 2 1 1 0 0 0 0 0 0 0 N 141 103 207 103 207 103 51 25 12 7 6 8 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0 -6.99 Rev. 2.0, 03/01, page 458 of 822  (MHz) 13 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 2 2 2 1 1 0 0 0 0 0 0 N 230 168 84 168 84 168 84 41 20 12 10 Error (%) -0.08 0.16 -0.43 0.16 -0.43 0.16 -0.43 0.76 0.76 0.00 -3.82 n 2 2 2 1 1 0 0 0 0 0 0 N 248 181 90 181 90 181 90 45 22 13 10 14 Error (%) -0.17 0.16 0.16 0.16 0.16 0.16 0.16 -0.93 -0.93 0 3.57 n 3 2 2 1 1 0 0 0 0 0 0 14.7456 N 64 191 95 191 95 191 95 47 23 14 11 Error (%) 0.70 0 0 0 0 0 0 0 0 -1.70 0 n 3 2 2 1 1 0 0 0 0 0 0 N 70 207 103 207 103 207 103 51 25 15 12 16 Error (%) 0.03 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0.16 0 0.16 (MHz) 18 Bit Rate (bits/s) 110 150 300 600 1200 2400 4800 9600 19200 31250 38400 n 3 2 2 1 1 0 0 0 0 0 0 N 79 233 116 233 116 233 116 58 28 17 14 Error (%) -0.12 0.16 0.16 0.16 0.16 0.16 0.16 -0.69 1.02 0.00 -2.34 n 3 3 2 2 1 1 0 0 0 0 0 N 88 64 129 64 129 64 129 64 32 19 15 20 Error (%) -0.25 0.16 0.16 0.16 0.16 0.16 0.16 0.16 -1.36 0.00 1.73 n 3 3 2 2 1 1 0 0 0 0 0 N 110 80 162 80 162 80 162 80 40 24 19 25 Error (%) -0.02 -0.47 0.15 -0.47 0.15 -0.47 0.15 -0.47 -0.76 0.00 1.73 Rev. 2.0, 03/01, page 459 of 822 Table 13.4 Examples of Bit Rates and BRR Settings in Synchronous Mode (MHz) Bit Rate (bits/s) n 110 250 500 1k 2.5 k 5k 10 k 25 k 50 k 100 k 250 k 500 k 1M 2M 2.5 M 4M Note: Settings with an error of 1% or less are recommended. Legend Blank: No setting available --: Setting possible, but error occurs Continuous transmit/receive not possible *: 3 2 1 1 0 0 0 0 0 0 0 0 2 N 70 124 249 124 199 99 49 19 9 4 1 0* n -- 2 2 1 1 0 0 0 0 0 0 0 0 4 N -- 249 124 249 99 199 99 39 19 9 3 1 0* n -- 3 2 2 1 1 0 0 0 0 0 0 0 0 -- 8 N -- 124 249 124 199 99 199 79 39 19 7 3 1 0* -- n -- -- -- -- 1 1 0 0 0 0 0 0 -- -- 0 10 N -- -- -- -- 249 124 249 99 49 24 9 4 -- -- 0* n -- 3 3 2 2 1 1 0 0 -- 0 -- -- -- -- 13 N -- 202 101 202 80 162 80 129 64 -- 12 -- -- -- -- Rev. 2.0, 03/01, page 460 of 822  (MHz) Bit Rate (bits/s) n 110 250 500 1k 2.5 k 5k 10 k 25 k 50 k 100 k 250 k 500 k 1M 2M 2.5 M 4M -- 3 3 2 2 1 1 0 0 0 0 0 0 0 -- 0 16 N -- 249 124 249 99 199 99 159 79 39 15 7 3 1 -- 0* n -- -- 3 3 2 1 1 0 0 0 0 0 0 -- -- -- 18 N -- -- 140 69 112 224 112 179 89 44 17 8 4 -- -- -- n -- -- 3 3 2 1 1 0 0 0 0 0 0 -- -- -- 20 N -- -- 155 77 124 249 124 199 99 49 19 9 4 -- -- -- n -- -- -- 3 2 2 1 0 0 0 0 -- -- -- -- -- 25 N -- -- -- 97 155 77 155 249 124 62 24 -- -- -- -- -- Note: Settings with an error of 1% or less are recommended. Legend Blank: No setting available --: Setting possible, but error occurs Continuous transmit/receive not possible *: Rev. 2.0, 03/01, page 461 of 822 The BRR setting is calculated as follows: Asynchronous mode: N= 64 x 22n-1 xB x 106 - 1 Synchronous mode: N= 8 x 22n-1 x B x 106 - 1 B: N: : n: Bit rate (bits/s) BRR setting for baud rate generator (0 N 255) System clock frequency (MHz) Baud rate generator clock source (n = 0, 1, 2, 3) (For the clock sources and values of n, see the following table.) SMR Settings n 0 1 2 3 Clock Source /4 /16 /64 CKS1 0 0 1 1 CKS0 0 1 0 1 The bit rate error in asynchronous mode is calculated as follows. x 106 (N + 1) x B x 64 x 22n-1 - 1 x 100 Error (%) = Rev. 2.0, 03/01, page 462 of 822 Table 13.5 indicates the maximum bit rates in asynchronous mode for various system clock frequencies. Tables 13.6 and 13.7 indicate the maximum bit rates with external clock input. Table 13.5 Maximum Bit Rates for Various Frequencies (Asynchronous Mode) Settings (MHz) 2 2.097152 2.4576 3 3.6864 4 4.9152 5 6 6.144 7.3728 8 9.8304 10 12 12.288 14 14.7456 16 17.2032 18 20 25 Maximum Bit Rate (bits/s) 62500 65536 76800 93750 115200 125000 153600 156250 187500 192000 230400 250000 307200 312500 375000 384000 437500 460800 500000 537600 562500 625000 781250 n 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 N 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Rev. 2.0, 03/01, page 463 of 822 Table 13.6 Maximum Bit Rates with External Clock Input (Asynchronous Mode) (MHz) 2 2.097152 2.4576 3 3.6864 4 4.9152 5 6 6.144 7.3728 8 9.8304 10 12 12.288 14 14.7456 16 17.2032 18 20 25 External Input Clock (MHz) 0.5000 0.5243 0.6144 0.7500 0.9216 1.0000 1.2288 1.2500 1.5000 1.5360 1.8432 2.0000 2.4576 2.5000 3.0000 3.0720 3.5000 3.6864 4.0000 4.3008 4.5000 5.0000 6.2500 Maximum Bit Rate (bits/s) 31250 32768 38400 46875 57600 62500 76800 78125 93750 96000 115200 125000 153600 156250 187500 192000 218750 230400 250000 268800 281250 312500 390625 Rev. 2.0, 03/01, page 464 of 822 Table 13.7 Maximum Bit Rates with External Clock Input (Synchronous Mode) (MHz) 2 4 6 8 10 12 14 16 18 20 25 External Input Clock (MHz) 0.3333 0.6667 1.0000 1.3333 1.6667 2.0000 2.3333 2.6667 3.0000 3.3333 4.1667 Maximum Bit Rate (bits/s) 333333.3 666666.7 1000000.0 1333333.3 1666666.7 2000000.0 2333333.3 2666666.7 3000000.0 3333333.3 4166666.7 Rev. 2.0, 03/01, page 465 of 822 13.3 13.3.1 Operation Overview The SCI has an asynchronous mode in which characters are synchronized individually, and a synchronous mode in which communication is synchronized with clock pulses. Serial communication is possible in either mode. Asynchronous or synchronous mode and the communication format are selected in SMR, as shown in table 13.8. The SCI clock source is selected by the C/$ bit in SMR and the CKE1 and CKE0 bits in SCR, as shown in table 13.9. Asynchronous Mode * Data length is selectable: 7 or 8 bits. * Parity and multiprocessor bits are selectable. So is the stop bit length (1 or 2 bits). These selections determine the communication format and character length. * In receiving, it is possible to detect framing errors, parity errors, overrun errors, and the break state. * An internal or external clock can be selected as the SCI clock source. When an internal clock is selected, the SCI operates using the on-chip baud rate generator, and can output a serial clock signal with a frequency matching the bit rate. When an external clock is selected, the external clock input must have a frequency 16 times the bit rate. (The on-chip baud rate generator is not used.) Synchronous Mode * The communication format has a fixed 8-bit data length. * In receiving, it is possible to detect overrun errors. * An internal or external clock can be selected as the SCI clock source. When an internal clock is selected, the SCI operates using the on-chip baud rate generator, and outputs a serial clock signal to external devices. When an external clock is selected, the SCI operates on the input serial clock. The on-chip baud rate generator is not used. Rev. 2.0, 03/01, page 466 of 822 Table 13.8 SMR Settings and Serial Communication Formats SMR Settings Bit 7: Bit 6: Bit 2: Bit 5: Bit 3: C/$ CHR MP PE STOP Mode $ 0 0 0 0 1 1 0 1 0 1 1 -- -- -- 1 -- 0 1 0 1 0 1 0 1 0 1 0 1 -- Synchronous mode 8-bit data Absent Asynchronous mode (multiprocessor format) 8-bit data 7-bit data Present Absent Present 7-bit data Absent Asynchronous mode SCI Communication Format Data Length 8-bit data Multiprocessor Parity Bit Bit Absent Absent Present Stop Bit Length 1 bit 2 bits 1 bit 2 bits 1 bit 2 bits 1 bit 2 bits 1 bit 2 bits 1 bit 2 bits None Table 13.9 SMR and SCR Settings and SCI Clock Source Selection SMR Bit 7: C/$ $ 0 SCR Settings Bit 1: CKE1 0 Bit 0: CKE0 0 1 1 1 0 1 0 1 0 1 0 1 Synchronous mode Internal External Mode Asynchronous mode Clock Source Internal SCI Transmit/Receive Clock SCK Pin Function SCI does not use the SCK pin Outputs a clock with frequency matching the bit rate External Inputs a clock with frequency 16 times the bit rate Outputs the serial clock Inputs the serial clock Rev. 2.0, 03/01, page 467 of 822 13.3.2 Operation in Asynchronous Mode In asynchronous mode each transmitted or received character begins with a start bit and ends with a stop bit. Serial communication is synchronized one character at a time. The transmitting and receiving sections of the SCI are independent, so full duplex communication is possible. The transmitter and receiver are both double buffered, so data can be written and read while transmitting and receiving are in progress, enabling continuous transmitting and receiving. Figure 13.2 shows the general format of asynchronous serial communication. In asynchronous serial communication the communication line is normally held in the mark (high) state. The SCI monitors the line and starts serial communication when the line goes to the space (low) state, indicating a start bit. One serial character consists of a start bit (low), data (LSB first), parity bit (high or low), and stop bit (high), in that order. When receiving in asynchronous mode, the SCI synchronizes at the falling edge of the start bit. The SCI samples each data bit on the eighth pulse of a clock with a frequency 16 times the bit rate. Receive data is latched at the center of each bit. 1 Serial data 0 Start bit 1 bit (LSB) D0 D1 D2 D3 D4 D5 D6 (MSB) D7 0/1 Parity bit 1 Idle (mark) state 1 1 Transmit or receive data 7 bits or 8 bits One unit of data (character or frame) Stop bit 1 bit or 1 bit or no bit 2 bits Figure 13.2 Data Format in Asynchronous Communication (Example: 8-Bit Data with Parity and 2 Stop Bits) Rev. 2.0, 03/01, page 468 of 822 Communication Formats: Table 13.10 shows the 12 communication formats that can be selected in asynchronous mode. The format is selected by settings in SMR. Table 13.10 Serial Communication Formats (Asynchronous Mode) SMR Settings CHR 0 PE 0 MP 0 STOP 0 1 S 2 Serial Communication Format and Frame Length 3 4 5 6 7 8 9 10 STOP 11 12 8-bit data 8-bit data 8-bit data 8-bit data 7-bit data 7-bit data 7-bit data 7-bit data 8-bit data 8-bit data 7-bit data 7-bit data STOP 0 0 0 1 S STOP STOP 0 1 0 0 S P STOP 0 1 0 1 S P STOP STOP 1 0 0 0 S 1 0 0 1 S STOP STOP 1 1 0 0 S P STOP 1 1 0 1 S P STOP STOP 0 -- 1 0 S MPB STOP 0 -- 1 1 S MPB STOP STOP 1 -- 1 0 S MPB STOP 1 -- 1 1 S MPB STOP STOP Legend S: Start bit STOP: Stop bit P: Parity bit MPB: Multiprocessor bit Rev. 2.0, 03/01, page 469 of 822 Clock: An internal clock generated by the on-chip baud rate generator or an external clock input from the SCK pin can be selected as the SCI transmit/receive clock. The clock source is selected by the C/$ bit in SMR and bits CKE1 and CKE0 in SCR. See table 13.9. When an external clock is input at the SCK pin, it must have a frequency equal to 16 times the desired bit rate. When the SCI operates on an internal clock, it can output a clock signal at the SCK pin. The frequency of this output clock is equal to the bit rate. The phase is aligned as in figure 13.3 so that the rising edge of the clock occurs at the center of each transmit data bit. 0 D0 D1 D2 D3 D4 D5 D6 D7 0/1 1 1 1 frame Figure 13.3 Phase Relationship between Output Clock and Serial Data (Asynchronous Mode) Transmitting and Receiving Data * SCI Initialization (Asynchronous Mode) Before transmitting or receiving, clear the TE and RE bits to 0 in SCR, then initialize the SCI as follows. When changing the communication mode or format, always clear the TE and RE bits to 0 before following the procedure given below. Clearing TE to 0 sets the TDRE flag to 1 and initializes TSR. Clearing RE to 0, however, does not initialize the RDRF, PER, FER, and ORER flags and RDR, which retain their previous contents. When an external clock is used, the clock should not be stopped during initialization or subsequent operation. SCI operation becomes unreliable if the clock is stopped. Figure 13.4 is a sample flowchart for initializing the SCI. Rev. 2.0, 03/01, page 470 of 822 Start of initialization 1. Select the clock source in SCR. Clear the RIE, TIE, TEIE, MPIE, TE, and RE bits to 0. If clock output is selected in asynchronous mode, clock output starts immediately after the setting is made in SCR. 2. Select the communication format in SMR. Set CKE1 and CKE0 bits in SCR (leaving TE and RE bits cleared to 0) 3. Write the value corresponding to the bit rate in BRR. This step is not necessary when an external clock is used. 4. Wait for at least the interval required to transmit or receive 1 bit, then set the TE or RE bit to 1 in SCR. Set the RIE, TIE, TEIE, and MPIE bits as necessary. Setting the TE or RE bit enables the SCI to use the TxD or RxD pin. Clear TE and RE bits to 0 in SCR 1 Select communication format in SMR 2 Set value in BRR Wait 3 1 bit interval elapsed? Yes Set TE or RE bit to 1 in SCR Set RIE, TIE, TEIE, and MPIE bits as necessary No 4 Transmitting or receiving Figure 13.4 Sample Flowchart for SCI Initialization Rev. 2.0, 03/01, page 471 of 822 * Transmitting Serial Data (Asynchronous Mode) Figure 13.5 shows a sample flowchart for transmitting serial data and indicates the procedure to follow. Initialize 1 Start transmitting 1. SCI initialization: the transmit data output function of the TxD pin is selected automatically. After the TE bit is set to 1, one frame of 1 is output, then transmission is possible. 2. SCI status check and transmit data write: read SSR, check that the TDRE flag is 1, then write transmit data in TDR and clear the TDRE flag to 0. 3. To continue transmitting serial data: after checking that the TDRE flag is 1, indicating that data can be written, write data in TDR, then clear the TDRE flag to 0. When the DMAC is activated by a transmit-dataempty interrupt request (TXI) to write data in TDR, the TDRE flag is checked and cleared automatically. 4. To output a break signal at the end of serial transmission: set the DDR bit to 1 and clear the DR bit to 0 (DDR and DR are I/O port registers), then clear the TE bit to 0 in SCR. Read TDRE flag in SSR No TDRE = 1? Yes Write transmit data in TDR and clear TDRE flag to 0 in SSR All data transmitted? Yes No 2 3 Read TEND flag in SSR No TEND = 1? Yes Output break signal? Yes Clear DR bit to 0, set DDR bit to 1 Clear TE bit to 0 in SCR No 4 End Figure 13.5 Sample Flowchart for Transmitting Serial Data Rev. 2.0, 03/01, page 472 of 822 In transmitting serial data, the SCI operates as follows. 1. The SCI monitors the TDRE flag in SSR. When the TDRE flag is cleared to 0 the SCI recognizes that TDR contains new data, and loads this data from TDR into TSR. 2. After loading the data from TDR into TSR, the SCI sets the TDRE flag to 1 and starts transmitting. If the TIE bit is set to 1 in SCR, the SCI requests a transmit-data-empty interrupt (TXI) at this time. Serial transmit data is transmitted in the following order from the TxD pin: a. Start bit: One 0 bit is output. b. Transmit data: 7 or 8 bits are output, LSB first. c. Parity bit or multiprocessor bit: One parity bit (even or odd parity) or one multiprocessor bit is output. Formats in which neither a parity bit nor a multiprocessor bit is output can also be selected. d. Stop bit: One or two 1 bits (stop bits) are output. e. Mark state: Output of 1 bits continues until the start bit of the next transmit data. 3. The SCI checks the TDRE flag when it outputs the stop bit. If the TDRE flag is 0, the SCI loads new data from TDR into TSR, outputs the stop bit, then begins serial transmission of the next frame. If the TDRE flag is 1, the SCI sets the TEND flag to 1 in SSR, outputs the stop bit, then continues output of 1 bits in the mark state. If the TEIE bit is set to 1 in SCR, a transmit-end interrupt (TEI) is requested at this time. Figure 13.6 shows an example of SCI transmit operation in asynchronous mode. 1 Start bit 0 D0 D1 Data D7 Parity Stop Start bit bit bit 0/1 1 0 D0 D1 Data D7 Parity Stop bit bit 0/1 1 1 Idle (mark) state TDRE TEND TXI interrupt request TXI interrupt handler writes data in TDR and clears TDRE flag to 0 1 frame TXI interrupt request TEI interrupt request Figure 13.6 Example of SCI Transmit Operation in Asynchronous Mode (8-Bit Data with Parity and 1 Stop Bit) Rev. 2.0, 03/01, page 473 of 822 * Receiving Serial Data (Asynchronous Mode) Figure 13.7 shows a sample flowchart for receiving serial data and indicates the procedure to follow. Initialize 1 1. SCI initialization: the receive data function of the RxD pin is selected automatically. 2, 3. Receive error handling and break detection: if a receive error occurs, read the ORER, PER, and FER flags in SSR to identify the error. After executing the necessary error handling, clear the ORER, PER, and FER flags all to 0. Receiving cannot resume if any of the ORER, PER, and FER flags remains set to 1. When a framing error occurs, the RxD pin can be read to detect the break state. 3 Start receiving Read ORER, PER, and FER flags in SSR 2 4. SCI status check and receive data read: read SSR, check that RDRF is set to 1, then read receive data from RDR and clear the RDRF Error handling No flag to 0. Notification that the RDRF flag has (continued on next page) changed from 0 to 1 can also be given by the RXI interrupt. Read RDRF flag in SSR 4 5. To continue receiving serial data: check the RDRF flag, read RDR, and clear the RDRF flag to 0 before the stop bit of the current No RDRF = 1? frame is received. If the DMAC is activated by an RXI interrupt to read the RDR value, the RDRF flag is cleared automatically. Yes Read receive data from RDR, and clear RDRF flag to 0 in SSR PER FER ORER = 1? Yes No Finished receiving? Yes Clear RE bit to 0 in SCR End 5 Figure 13.7 Sample Flowchart for Receiving Serial Data (1) Rev. 2.0, 03/01, page 474 of 822 3 Error handling No ORER = 1? Yes Overrun error handling No FER = 1? Yes Break? No Framing error handling Clear RE bit to 0 in SCR Yes No PER = 1? Yes Parity error handling Clear ORER, PER, and FER flags to 0 in SSR End Figure 13.7 Sample Flowchart for Receiving Serial Data (2) Rev. 2.0, 03/01, page 475 of 822 In receiving, the SCI operates as follows. 1. The SCI monitors the receive data line. When it detects a start bit, the SCI synchronizes internally and starts receiving. 2. Receive data is stored in RSR in order from LSB to MSB. 3. The parity bit and stop bit are received. After receiving, the SCI makes the following checks: a. Parity check: The number of 1s in the receive data must match the even or odd parity setting of the O/( bit in SMR. b. Stop bit check: The stop bit value must be 1. If there are two stop bits, only the first stop bit is checked. c. Status check: The RDRF flag must be 0 so that receive data can be transferred from RSR into RDR. If these checks all pass, the RDRF flag is set to 1 and the received data is stored in RDR. If one of the checks fails (receive error), the SCI operates as indicated in table 13.11. Note: When a receive error occurs, further receiving is disabled. In receiving, the RDRF flag is not set to 1. Be sure to clear the error flags to 0. 4. When the RDRF flag is set to 1, if the RIE bit is set to 1 in SCR, a receive-data-full interrupt (RXI) is requested. If the ORER, PER, or FER flag is set to 1 and the RIE bit in SCR is also set to 1, a receive-error interrupt (ERI) is requested. Table 13.11 Receive Error Conditions Receive Error Overrun error Abbreviation ORER Condition Receiving of next data ends while RDRF flag is still set to 1 in SSR Stop bit is 0 Parity of receive data differs from even/odd parity setting in SMR Data Transfer Receive data not transferred from RSR to RDR Receive data transferred from RSR to RDR Receive data transferred from RSR to RDR Framing error Parity error FER PER Rev. 2.0, 03/01, page 476 of 822 Figure 13.8 shows an example of SCI receive operation in asynchronous mode. 1 Start bit 0 Data D0 D1 D7 Parity Stop Start bit bit bit 0/1 1 0 Data D0 D1 D7 Parity Stop bit bit 0/1 1 1 Idle (mark) state RDRF FER RXI request 1 frame RXI interrupt handler reads data in RDR and clears RDRF flag to 0 Framing error, ERI request Figure 13.8 Example of SCI Receive Operation (8-Bit Data with Parity and One Stop Bit) 13.3.3 Multiprocessor Communication The multiprocessor communication function enables several processors to share a single serial communication line. The processors communicate in asynchronous mode using a format with an additional multiprocessor bit (multiprocessor format). In multiprocessor communication, each receiving processor is addressed by an ID. A serial communication cycle consists of an ID-sending cycle that identifies the receiving processor, and a data-sending cycle. The multiprocessor bit distinguishes ID-sending cycles from data-sending cycles. The transmitting processor starts by sending the ID of the receiving processor with which it wants to communicate as data with the multiprocessor bit set to 1. Next the transmitting processor sends transmit data with the multiprocessor bit cleared to 0. Receiving processors skip incoming data until they receive data with the multiprocessor bit set to 1. When they receive data with the multiprocessor bit set to 1, receiving processors compare the data with their IDs. The receiving processor with a matching ID continues to receive further incoming data. Processors with IDs not matching the received data skip further incoming data until they again receive data with the multiprocessor bit set to 1. Multiple processors can send and receive data in this way. Figure 13.9 shows an example of communication among different processors using a multiprocessor format. Rev. 2.0, 03/01, page 477 of 822 Communication Formats: Four formats are available. Parity-bit settings are ignored when a multiprocessor format is selected. For details see table 13.10. Clock: See the description of asynchronous mode. Transmitting processor Serial communication line Receiving processor A (ID = 01) Receiving processor B (ID = 02) Receiving processor C (ID = 03) Receiving processor D (ID = 04) Serial data H'01 (MPB = 1) ID-sending cycle: receiving processor address H'AA (MPB = 0) Data-sending cycle: data sent to receiving processor specified by ID Legend MPB: Multiprocessor bit Figure 13.9 Example of Communication among Processors using Multiprocessor Format (Sending Data H'AA to Receiving Processor A) Rev. 2.0, 03/01, page 478 of 822 Transmitting and Receiving Data * Transmitting Multiprocessor Serial Data Figure 13.10 shows a sample flowchart for transmitting multiprocessor serial data and indicates the procedure to follow. Initialize Start transmitting 1 1. SCI initialization: the transmit data output function of the TxD pin is selected automatically. 2. SCI status check and transmit data write: read SSR, check that the TDRE flag is 1, then write transmit data in TDR. Also set the MPBT flag to 0 or 1 in SSR. Finally, clear the TDRE flag to 0. 3. To continue transmitting serial data: after checking that the TDRE flag is 1, indicating that data can be written, write data in TDR, then clear the TDRE flag to 0. When the DMAC is activated by a transmit-data-empty interrupt request (TXI) to write data in TDR, the TDRE flag is checked and cleared automatically. Read TDRE flag in SSR No 2 TDRE = 1? Yes Write transmit data in TDR and set MPBT bit in SSR Clear TDRE flag to 0 No All data transmitted? Yes Read TEND flag in SSR No TEND = 1? Yes Output break signal? Yes Clear DR bit to 0, set DDR bit to 1 Clear TE bit to 0 in SCR No 4 3 4. To output a break signal at the end of serial transmission: set the DDR bit to 1 and clear the DR bit to 0 (DDR and DR are I/O port registers), then clear the TE bit to 0 in SCR. End Figure 13.10 Sample Flowchart for Transmitting Multiprocessor Serial Data Rev. 2.0, 03/01, page 479 of 822 In transmitting serial data, the SCI operates as follows. 1. The SCI monitors the TDRE flag in SSR. When the TDRE flag is cleared to 0 the SCI recognizes that TDR contains new data, and loads this data from TDR into TSR. 2. After loading the data from TDR into TSR, the SCI sets the TDRE flag to 1 and starts transmitting. If the TIE bit in SCR is set to 1, the SCI requests a transmit-data-empty interrupt (TXI) at this time. Serial transmit data is transmitted in the following order from the TxD pin: a. Start bit: One 0 bit is output. b. Transmit data: 7 or 8 bits are output, LSB first. c. Multiprocessor bit: One multiprocessor bit (MPBT value) is output. d. Stop bit: One or two 1 bits (stop bits) are output. e. Mark state: Output of 1 bits continues until the start bit of the next transmit data. 3. The SCI checks the TDRE flag when it outputs the stop bit. If the TDRE flag is 0, the SCI loads data from TDR into TSR, outputs the stop bit, then begins serial transmission of the next frame. If the TDRE flag is 1, the SCI sets the TEND flag in SSR to 1, outputs the stop bit, then continues output of 1 bits in the mark state. If the TEIE bit is set to 1 in SCR, a transmit-end interrupt (TEI) is requested at this time. Figure 13.11 shows an example of SCI transmit operation using a multiprocessor format. Multiprocessor bit 1 Start bit 0 D0 D1 Data D7 0/1 Stop Start bit bit 1 0 D0 D1 Data D7 Multiprocessor bit Stop bit 0/1 1 1 Idle (mark) state TDRE TEND TXI request TXI interrupt handler writes data in TDR and clears TDRE flag to 0 1 frame TXI request TEI request Figure 13.11 Example of SCI Transmit Operation (8-Bit Data with Multiprocessor Bit and One Stop Bit) Rev. 2.0, 03/01, page 480 of 822 * Receiving Multiprocessor Serial Data Figure 13.12 shows a sample flowchart for receiving multiprocessor serial data and indicates the procedure to follow. 1. SCI initialization: the receive data function of the RxD pin is selected automatically. 2. ID receive cycle: set the MPIE bit to 1 in SCR. 2 3. SCI status check and ID check: read SSR, check that the RDRF flag is set to 1, then read data from RDR and compare with the processor's own ID. If the ID does not match, set the MPIE bit to 1 again and clear the RDRF flag to 0. If the ID matches, clear the RDRF flag to 0. 4. SCI status check and data receiving: read SSR, check that the RDRF flag is set to 1, then read data from RDR. 5. Receive error handling and break detection: if a receive error occurs, read the ORER and FER flags in SSR to identify the error. After executing the necessary error handling, clear the ORER and FER flags both to 0. Receiving cannot resume while either the ORER or FER flag remains set to 1. When a framing error occurs, the RxD pin can be read to detect the break state. 4 No RDRF = 1? Yes Read receive data from RDR No No Finished receiving? Yes Clear RE bit to 0 in SCR End 5 Error handling (continued on next page) Initialize Start receiving 1 Set MPIE bit to 1 in SCR Read ORER and FER flags in SSR FER ORER = 1 No Read RDRF flag in SSR No RDRF = 1? Yes Read receive data from RDR No Own ID? Yes Read ORER and FER flags in SSR FER ORER = 1 No Read RDRF flag in SSR Yes 3 Yes Figure 13.12 Sample Flowchart for Receiving Multiprocessor Serial Data (1) Rev. 2.0, 03/01, page 481 of 822 5 Error handling No ORER = 1? Yes Overrun error handling No FER = 1? Yes Break? No Framing error handling Clear RE bit to 0 in SCR Yes Clear ORER, PER, and FER flags to 0 in SSR End Figure 13.12 Sample Flowchart for Receiving Multiprocessor Serial Data (2) Figure 13.13 shows an example of SCI receive operation using a multiprocessor format. Rev. 2.0, 03/01, page 482 of 822 1 Start bit 0 Data (ID1) MPB D7 1 Stop Start Data (data1) bit bit 1 0 MPB D7 0 Stop bit 1 1 D0 D1 D0 D1 Idle (mark) state MPIE RDRF RDR value MPB detection MPIE= 0 RXI request (multiprocessor interrupt) RXI handler reads RDR data and clears RDRF flag to 0 ID1 Not own ID, so MPIE bit is set to 1 again No RXI request, RDR not updated a. Own ID does not match data 1 Start bit 0 Data (ID2) MPB D7 1 Stop Start Data (data2) bit bit 1 0 MPB D7 0 Stop bit 1 1 D0 D1 D0 D1 Idle (mark) state MPIE RDRF RDR value MPB detection MPIE= 0 RXI request (multiprocessor interrupt) ID2 Data 2 RXI interrupt handler Own ID, so receiving MPIE bit is set reads RDR data and continues, with data to 1 again clears RDRF flag to 0 received by RXI interrupt handler b. Own ID matches data Figure 13.13 Example of SCI Receive Operation (8-Bit Data with Multiprocessor Bit and One Stop Bit) Rev. 2.0, 03/01, page 483 of 822 13.3.4 Synchronous Operation In synchronous mode, the SCI transmits and receives data in synchronization with clock pulses. This mode is suitable for high-speed serial communication. The SCI transmitter and receiver share the same clock but are otherwise independent, so full duplex communication is possible. The transmitter and receiver are also double buffered, so continuous transmitting or receiving is possible by reading or writing data while transmitting or receiving is in progress. Figure 13.14 shows the general format in synchronous serial communication. One unit (character or frame) of serial data * Serial clock LSB Serial data Don't care Note: * High except in continuous transmitting or receiving Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 MSB Bit 7 Don't care * Figure 13.14 Data Format in Synchronous Communication In synchronous serial communication, each data bit is placed on the communication line from one falling edge of the serial clock to the next. Data is guaranteed valid at the rise of the serial clock. In each character, the serial data bits are transmitted in order from LSB (first) to MSB (last). After output of the MSB, the communication line remains in the state of the MSB. In synchronous mode the SCI receives data by synchronizing with the rise of the serial clock. Communication Format: The data length is fixed at 8 bits. No parity bit or multiprocessor bit can be added. Clock: An internal clock generated by the on-chip baud rate generator or an external serial clock input from the SCK pin can be selected by means of the C/$ bit in SMR and bits CKE1 and CKE0 in SCR. See table 13.9 for details of SCI clock source selection. When the SCI operates on an internal clock, the serial clock is output from the SCK pin. Eight serial clock pulses are output per transmitted or received character. When the SCI is not transmitting or receiving, the clock signal remains in the high state. However, in a receive-only operation, the serial clock is output until an overrun error occurs or the RE bit is cleared to 0. For character-by-character reception, an external clock should be selected as the clock source. Rev. 2.0, 03/01, page 484 of 822 Transmitting and Receiving Data * SCI Initialization (Synchronous Mode) Before transmitting or receiving, clear the TE and RE bits to 0 in SCR, then initialize the SCI as follows. When changing the communication mode or format, always clear the TE and RE bits to 0 before following the procedure given below. Clearing the TE bit to 0 sets the TDRE flag to 1 and initializes TSR. Clearing the RE bit to 0, however, does not initialize the RDRF, PER, FER, and ORE flags and RDR, which retain their previous contents. Figure 13.15 is a sample flowchart for initializing the SCI. Start of initialization 1. Select the clock source in SCR. Clear the RIE, TIE, TEIE, MPIE, TE, and RE bits to 0. 2. Select the communication format in SMR. 3. Write the value corresponding to the bit rate in BRR. This step is not necessary when an external clock is used. 1 4. Wait for at least the interval required to transmit or receive one bit, then set the TE or RE bit to 1 in SCR. Also set the RIE, TIE, TEIE, and MPIE bits as necessary. Setting the TE or RE bit enab les the SCI to use the TxD or RxD pin. Clear TE and RE bits to 0 in SCR Set RIE, TIE, TEIE, MPIE, CKE1, and CKE0 bits in SCR (leaving TE and RE bits cleared to 0) Select communication format in SMR 2 Set value in BRR Wait 1 bit interval elapsed? Yes Set TE or RE to 1 in SCR Set RIE, TIE, TEIE, and MPIE bits as necessary No 3 4 Start transmitting or receiving Note: In simultaneous transmitting and receiving, the TE and RE bits should be cleared to 0 or set to 1 simultaneously Figure 13.15 Sample Flowchart for SCI Initialization Rev. 2.0, 03/01, page 485 of 822 * Transmitting Serial Data (Synchronous Mode) Figure 13.16 shows a sample flowchart for transmitting serial data and indicates the procedure to follow. Initialize 1 Start transmitting 1. SCI initialization: the transmit data output function of the TxD pin is selected automatically. After setting TE bit to 1, output 1 from frame one transmission is possible. 2. SCI status check and transmit data write: read SSR, check that the TDRE flag is 1, then write transmit data in TDR and clear the TDRE flag to 0. 3. To continue transmitting serial data: after checking that the TDRE flag is 1, indicating that data can be written, write data in TDR, then clear the TDRE flag to 0. When the DMAC is activated by a transmit-data-empty interrupt request (TXI) to write data in TDR, the TDRE flag is checked and cleared automatically. Read TDRE flag in SSR 2 No TDRE = 1? Yes Write transmit data in TDR and clear TDRE flag to 0 in SSR All data transmitted? Yes No 3 Read TEND flag in SSR No TEND = 1? Yes Clear TE bit to 0 in SCR End Figure 13.16 Sample Flowchart for Serial Transmitting Rev. 2.0, 03/01, page 486 of 822 In transmitting serial data, the SCI operates as follows. 1. The SCI monitors the TDRE flag in SSR. When the TDRE flag is cleared to 0 the SCI recognizes that TDR contains new data, and loads this data from TDR into TSR. 2. After loading the data from TDR into TSR, the SCI sets the TDRE flag to 1 and starts transmitting. If the TIE bit is set to 1 in SCR, the SCI requests a transmit-data-empty interrupt (TXI) at this time. If clock output is selected, the SCI outputs eight serial clock pulses. If an external clock source is selected, the SCI outputs data in synchronization with the input clock. Data is output from the TxD pin in order from LSB (bit 0) to MSB (bit 7). 3. The SCI checks the TDRE flag when it outputs the MSB (bit 7). If the TDRE flag is 0, the SCI loads data from TDR into TSR and begins serial transmission of the next frame. If the TDRE flag is 1, the SCI sets the TEND flag to 1 in SSR, and after transmitting the MSB, holds the TxD pin in the MSB state. If the TEIE bit in SCR is set to 1, a transmit-end interrupt (TEI) is requested at this time. 4. After the end of serial transmission, the SCK pin is held in a constant state. Figure 13.17 shows an example of SCI transmit operation. Transmit direction Serial clock Serial data TDRE TEND TXI request Bit 0 Bit 1 Bit 7 Bit 0 Bit 1 Bit 6 Bit 7 TXI interrupt handler writes data in TDR and clears TDRE flag to 0 1 frame TXI request TEI request Figure 13.17 Example of SCI Transmit Operation Rev. 2.0, 03/01, page 487 of 822 * Receiving Serial Data Figure 13.18 shows a sample flowchart for receiving serial data and indicates the procedure to follow. When switching from asynchronous mode to synchronous mode, make sure that the ORER, PER, and FER flags are cleared to 0. If the FER or PER flag is set to 1 the RDRF flag will not be set and both transmitting and receiving will be disabled. Initialize 1 1. SCI initialization: the receive data function of the RxD pin is selected automatically. 2, 3. Receive error handling: if a receive error occurs, read the ORER flag in SSR, then after executing the necessary error handling, clear the ORER flag to 0. Neither transmitting nor receiving can resume while the ORER flag remains set to 1. 4. SCI status check and receive data read: read SSR, check that the RDRF flag is set to 1, then read receive data from RDR and clear the RDRF flag to 0. Notification that the RDRF flag has changed from 0 to 1 can also be given by the RXI interrupt. 5. To continue receiving serial data: check the RDRF flag, read RDR, and clear the RDRF flag to 0 before the MSB (bit 7) of the current frame is received. If the DMAC is activated by a receive-data-full interrupt request (RXI) to read RDR, the RDRF flag is cleared automatically. Start receiving Read ORER flag in SSR 2 ORER = 1? No Read RDRF flag in SSR No RDRF = 1? Yes Read receive data from RDR, and clear RDRF flag to 0 in SSR Yes 3 Error handling continued on next page 4 5 No Finished receiving? Yes Clear RE bit to 0 in SCR End Figure 13.18 Sample Flowchart for Serial Receiving (1) Rev. 2.0, 03/01, page 488 of 822 3 Error handling Overrun error handling Clear ORER flag to 0 in SSR End Figure 13.18 Sample Flowchart for Serial Receiving (2) In receiving, the SCI operates as follows. 1. The SCI synchronizes with serial clock input or output and initializes internally. 2. Receive data is stored in RSR in order from LSB to MSB. After receiving the data, the SCI checks that the RDRF flag is 0 so that receive data can be transferred from RSR to RDR. If this check passes, the RDRF flag is set to 1 and the received data is stored in RDR. If the check does not pass (receive error), the SCI operates as indicated in table 13.11. When a receive error has been identified in the error check, subsequent transmit and receive operations are disabled. 3. After setting the RDRF flag to 1, if the RIE bit is set to 1 in SCR, the SCI requests a receive-data-full interrupt (RXI). If the ORER flag is set to 1 and the RIE bit in SCR is also set to 1, the SCI requests a receive-error interrupt (ERI). Figure 13.19 shows an example of SCI receive operation. Rev. 2.0, 03/01, page 489 of 822 Serial clock Serial data RDRF Bit 7 Bit 0 Bit 7 Bit 0 Bit 1 Bit 6 Bit 7 ORER RXI request RXI interrupt handler reads data in RDR and clears RDRF flag to 0 1 frame RXI request Overrun error, ERI request Figure 13.19 Example of SCI Receive Operation * Transmitting and Receiving Serial Data Simultaneously (Synchronous Mode) Figure 13.20 shows a sample flowchart for transmitting and receiving serial data simultaneously and indicates the procedure to follow. Rev. 2.0, 03/01, page 490 of 822 Initialize 1 Start transmitting and receiving 1. SCI initialization: the transmit data output function of the TxD pin and receive data input function of the RxD pin are selected, enabling simultaneous transmitting and receiving. 2. SCI status check and transmit data write: read SSR, check that the TDRE flag is 1, then write transmit data in TDR and clear the TDRE flag to 0. Notification that the TDRE flag has changed from 0 to 1 can also be given by the TXI interrupt. 3. Receive error handling: if a receive error occurs, read the ORER flag in SSR, then after executing the necessary error handling, clear the ORER flag to 0. Neither transmitting nor receiving can resume while the ORER flag remains set to 1. 4. SCI status check and receive data read: read SSR, check that the RDRF flag is 1, then read receive data from RDR and clear the RDRF flag to 0. Notification that the RDRF flag has changed from 0 to 1 can also be given by the RXI interrupt. 5. To continue transmitting and receiving serial data: check the RDRF flag, read RDR, and clear the RDRF flag to 0 before the MSB (bit 7) of the current frame is received. Also check that the TDRE flag is set to 1, indicating that data can be written, write data in TDR, then clear the TDRE flag to 0 before the MSB (bit 7) of the current frame is transmitted. When the DMAC is activated by a transmit-data-empty interrupt request (TXI) to write data in TDR, the TDRE flag is checked and cleared automatically. When the DMA C is activated by a receive-data-full interrupt request (RXI) to read RDR, the RDRF flag is cleared automatically. Read TDRE flag in SSR No TDRE = 1? Yes Write transmit data in TDR and clear TDRE flag to 0 in SSR 2 Read ORER flag in SSR Yes 3 Error handling 4 ORER = 1? No Read RDRF flag in SSR No RDRF = 1? Yes Read receive data from RDR and clear RDRF flag to 0 in SSR No End of transmitting and receiving? Yes Clear TE and RE bits to 0 in SCR 5 End Note: When switching from transmitting or receiving to simultaneous transmitting and receiving, clear both the TE bit and the RE bit to 0, then set both bits to 1. Figure 13.20 Sample Flowchart for Serial Transmitting Rev. 2.0, 03/01, page 491 of 822 13.4 SCI Interrupts The SCI has four interrupt request sources: TEI (transmit-end interrupt), ERI (receive-error interrupt), RXI (receive-data-full interrupt), and TXI (transmit-data-empty interrupt). Table 13.12 lists the interrupt sources and indicates their priority. These interrupts can be enabled and disabled by the TIE, TEIE, and RIE bits in SCR. Each interrupt request is sent separately to the interrupt controller. The TXI interrupt is requested when the TDRE flag is set to 1 in SSR. The TEI interrupt is requested when the TEND flag is set to 1 in SSR. The TXI interrupt request can activate the DMAC to transfer data. Data transfer by the DMAC automatically clears the TDRE flag to 0. The TEI interrupt request cannot activate the DMAC. The RXI interrupt is requested when the RDRF flag is set to 1 in SSR. The ERI interrupt is requested when the ORER, PER, or FER flag is set to 1 in SSR. The RXI interrupt request can activate the DMAC to transfer data. Data transfer by the DMAC automatically clears the RDRF flag to 0. The ERI interrupt request cannot activate the DMAC. The DMAC can be activated by interrupts from SCI channel 0. Table 13.12 SCI Interrupt Sources Interrupt ERI RXI TXI TEI Description Receive error (ORER, FER, or PER) Receive data register full (RDRF) Transmit data register empty (TDRE) Transmit end (TEND) Priority High Low Rev. 2.0, 03/01, page 492 of 822 13.5 Usage Notes Note the following points when using the SCI. TDR Write and TDRE Flag: The TDRE flag in SSR is a status flag indicating the loading of transmit data from TDR into TSR. The SCI sets the TDRE flag to 1 when it transfers data from TDR to TSR. Data can be written into TDR regardless of the state of the TDRE flag. If new data is written in TDR when the TDRE flag is 0, the old data stored in TDR will be lost because this data has not yet been transferred to TSR. Before writing transmit data in TDR, be sure to check that the TDRE flag is set to 1. Simultaneous Multiple Receive Errors: Table 13.13 indicates the state of SSR status flags when multiple receive errors occur simultaneously. When an overrun error occurs the RSR contents are not transferred to RDR, so receive data is lost. Table 13.13 SSR Status Flags and Transfer of Receive Data Receive Data Transfer RSR RDR x O O x x O x RDRF 1 0 0 1 1 0 1 ORER 1 0 0 1 1 0 1 FER 0 1 0 1 0 1 1 PER 0 0 1 0 1 1 1 Receive Errors Overrun error Framing error Parity error Overrun error + framing error Overrun error + parity error Framing error + parity error Overrun error + framing error + parity error Notes: O: Receive data is transferred from RSR to RDR. x : Receive data is not transferred from RSR to RDR. Rev. 2.0, 03/01, page 493 of 822 Break Detection and Processing: Break signals can be detected by reading the RxD pin directly when a framing error (FER) is detected. In the break state the input from the RxD pin consists of all 0s, so the FER flag is set and the parity error flag (PER) may also be set. In the break state the SCI receiver continues to operate, so if the FER flag is cleared to 0 it will be set to 1 again. Sending a Break Signal: When the TE bit is cleared to 0 the TxD pin becomes an I/O port, the level and direction (input or output) of which are determined by DR and DDR bits. This feature can be used to send a break signal. After the serial transmitter is initialized, the DR value substitutes for the mark state until the TE bit is set to 1 (the TxD pin function is not selected until the TE bit is set to 1). The DDR and DR bits should therefore both be set to 1 beforehand. To send a break signal during serial transmission, clear the DR bit to 0, then clear the TE bit to 0. When the TE bit is cleared to 0 the transmitter is initialized, regardless of its current state, so the TxD pin becomes an output port outputting the value 0. Receive Error Flags and Transmitter Operation (Synchronous Mode Only): When a receive error flag (ORER, PER, or FER) is set to 1 the SCI will not start transmitting, even if the TDRE flag is cleared to 0. Be sure to clear the receive error flags to 0 when starting to transmit. Note that clearing the RE bit to 0 does not clear the receive error flags to 0. Receive Data Sampling Timing in Asynchronous Mode and Receive Margin: In asynchronous mode the SCI operates on a base clock with 16 times the bit rate frequency. In receiving, the SCI synchronizes internally with the fall of the start bit, which it samples on the base clock. Receive data is latched at the rising edge of the eighth base clock pulse. See figure 13.21. 16 clocks 8 clocks 0 Internal base clock 7 15 0 7 15 0 Receive data (RxD) Start bit D0 D1 Synchronization sampling timing Data sampling timing Figure 13.21 Receive Data Sampling Timing in Asynchronous Mode Rev. 2.0, 03/01, page 494 of 822 The receive margin in asynchronous mode can therefore be expressed as in equation (1). M = (0.5 - 1 2N ) - (L - 0.5) F - D - 0.5 N (1 + F) x 100% ................... (1) M: N: D: L: F: Receive margin (%) Ratio of clock frequency to bit rate (N = 16) Clock duty cycle (D = 0 to 1.0) Frame length (L = 9 to 12) Absolute deviation of clock frequency From equation (1), if F = 0 and D = 0.5 the receive margin is 46.875%, as given by equation (2). D = 0.5, F = 0 M = {0.5 - 1/(2 x 16)} x 100% = 46.875% ............................................................................................. (2) This is a theoretical value. A reasonable margin to allow in system designs is 20% to 30%. Restrictions on Usage of DMAC: To have the DMAC read RDR, be sure to select the SCI receive-data-full interrupt (RXI) as the activation source with bits DTS2 to DTS0 in DTCR. Restrictions on Usage of the Serial Clock: When transmitting data using the serial clock as an external clock, after clearing SSR of TDRE, maintain the space between each frame of the lead of the transmission clock (start-up edge) at five states or more (see Figure 13.22). This condition is also needed for continuous transmission. If it is not fulfilled, operational error will occur. SCK t* TDRE t* TXD X0 X1 X2 X3 X4 X5 X6 X7 Y0 Y1 Y2 Y3 Continuous transmission Note: * Ensure that t 5 states. Figure 13.22 Serial Clock Transmission (Example) Rev. 2.0, 03/01, page 495 of 822 Switching SCK Pin to Port Output Pin Function in Synchronous Mode: When the SCK pin is used as the serial clock output in synchronous mode, and is then switched to its output port function at the end of transmission, a low level may be output for one half-cycle. Half-cycle lowlevel output occurs when SCK is switched to its port function with the following settings when DDR = 1, DR = 1, C/$ = 1, CKE1 = 0, CKE0 = 0, and TE = 1. 1. End of serial data transmission 2. TE bit = 0 3. C/$ bit = 0 ... switchover to port outpu 4. Occurrence of low-level output (see figure 13.23) Half-cycle low-level output SCK/port 1. End of transmission Data TE C/ CKE1 CKE0 Bit 6 Bit 7 2. TE = 0 4. Low-level output 3. C/ = 0 Figure 13.23 Operation when Switching from SCK Pin Function to Port Pin Function Rev. 2.0, 03/01, page 496 of 822 Sample Procedure for Avoiding Low-Level Output As this sample procedure temporarily places the SCK pin in the input state, the SCK/port pin should be pulled up beforehand with an external circuit. With DDR = 1, DR = 1, C/$ = 1, CKE1 = 0, CKE0 = 0, and TE = 1, make the following settings in the order shown. 1. End of serial data transmission 2. TE bit = 0 3. CKE1 bit = 1 4. C/$ bit = 0 ... switchover to port output 5. CKE1 bit = 0 High-level output SCK/port 1. End of transmission Data TE C/ 3. CKE1 = 1 CKE1 CKE0 5. CKE1 = 0 Bit 6 Bit 7 2. TE = 0 4. C/ = 0 Figure 13.24 Operation when Switching from SCK Pin Function to Port Pin Function (Example of Preventing Low-Level Output) Rev. 2.0, 03/01, page 497 of 822 Rev. 2.0, 03/01, page 498 of 822 Section 14 Smart Card Interface 14.1 Overview As an extension of its serial communication interface functions, SCI0 supports a smart card (IC card) interface conforming to the ISO/IEC7816-3 (Identification Card) standard. Switchover between normal serial communication and the smart card interface is controlled by a register setting. 14.1.1 Features Features of the smart-card interface supported by the H8/3052F are listed below. * Asynchronous communication Data length: 8 bits Parity bits generated and checked Error signal output in receive mode (parity error) Error signal detect and automatic data retransmit in transmit mode Supports both direct convention and inverse convention * Built-in baud rate generator with selectable bit rates * Three types of interrupts Transmit-data-empty, receive-data-full, and receive-error interrupts are requested independently. The transmit-data-empty and receive-data-full interrupts can activate the DMA controller (DMAC) to transfer data. Rev. 2.0, 03/01, page 499 of 822 14.1.2 Block Diagram Figure 14.1 shows a block diagram of the smart card interface. Bus interface Module data bus Internal data bus RDR TDR RxD0 RSR TSR SCMR SSR SCR SMR Transmit/receive control BRR /4 Baud rate generator Clock /16 /64 TxD0 Parity generate Parity check SCK0 TXI RXI ERI Legend SCMR: RSR: RDR: TSR: TDR: SMR: SCR: SSR: BRR: Smart card mode register Receive shift register Receive data register Transmit shift register Transmit data register Serial mode register Serial control register Serial status register Bit rate register Figure 14.1 Smart Card Interface Block Diagram Rev. 2.0, 03/01, page 500 of 822 14.1.3 Pin Configuration Table 14.1 lists the smart card interface pins. Table 14.1 Smart Card Interface Pins Name Serial clock pin Receive data pin Transmit data pin Abbreviation SCK0 RxD0 TxD0 I/O Output Input Output Function Clock output Receive data input Transmit data output 14.1.4 Register Configuration The smart card interface has the internal registers listed in table 14.2. BRR, TDR, and RDR have their normal serial communication interface functions, as described in section 13, Serial Communication Interface. Table 14.2 Registers Address* H'FFB0 H'FFB1 H'FFB2 H'FFB3 H'FFB4 H'FFB5 H'FFB6 1 Name Serial mode register Bit rate register Serial control register Transmit data register Serial status register Receive data register Smart card mode register Abbreviation SMR BRR SCR TDR SSR RDR SCMR R/W R/W R/W R/W R/W R/(W) * R R/W 2 Initial Value H'00 H'FF H'00 H'FF F'84 H'00 H'F2 Notes: 1. Lower 16 bits of the address. 2. Only 0 can be written, to clear flags. Rev. 2.0, 03/01, page 501 of 822 14.2 Register Descriptions This section describes the new or modified registers and bit functions in the smart card interface. 14.2.1 Smart Card Mode Register (SCMR) SCMR is an 8-bit readable/writable register that selects smart card interface functions. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 SDIR 0 R/W 2 SINV 0 R/W 1 -- 1 -- 0 SMIF 0 R/W Reserved bits Smart card interface mode select Enables or disables the smart card interface function Smart card data invert Inverts data logic levels Smart card data transfer direction Selects the serial/parallel conversion format Reserved bits SCMR is initialized to H'F2 by a reset and in standby mode. Bits 7 to 4--Reserved: Read-only bits, always read as 1. Bit 3--Smart Card Data Transfer Direction (SDIR): Selects the serial/parallel conversion format. Bit 3: SDIR 0 1 Description TDR contents are transmitted LSB-first Received data is stored LSB-first in RDR TDR contents are transmitted MSB-first Received data is stored MSB-first in RDR (Initial value) Rev. 2.0, 03/01, page 502 of 822 Bit 2--Smart Card Data Inverter (SINV): Inverts data logic levels. This function is used in combination with bit 3 to communicate with inverse-convention cards. SINV does not affect the logic level of the parity bit. For parity settings, see section 14.3.4, Register Settings. Bit 2: SINV 0 1 Description Unmodified TDR contents are transmitted Received data is stored unmodified in RDR Inverted TDR contents are transmitted Received data is inverted before storage in RDR (Initial value) Bit 1--Reserved: Read-only bit, always read as 1. Bit 0--Smart Card Interface Mode Select (SMIF): Enables the smart card interface function. Bit 0: SMIF 0 1 Description Smart card interface function is disabled Smart card interface function is enabled (Initial value) 14.2.2 Serial Status Register (SSR) The function of SSR bit 4 is modified in the smart card interface. This change also causes a modification to the setting conditions for bit 2 (TEND). Bit Initial value Read/Write 7 TDRE 1 R/(W)* 6 RDRF 0 R/(W)* 5 ORER 0 R/(W)* 4 ERS 0 R/(W)* 3 PER 0 R/(W)* 2 TEND 1 R 1 MPB 0 R 0 MPBT 0 R/W Transmit end Status flag indicating end of transmission Error signal status (ERS) Status flag indicating that an error signal has been received Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 503 of 822 Bits 7 to 5: These bits operate as in normal serial communication. For details see section 13, Serial Communication Interface. Bit 4--Error Signal Status (ERS): In smart card interface mode, this flag indicates the status of the error signal sent from the receiving device to the transmitting device. The smart card interface does not detect framing errors. Bit 4: ERS 0 Description Indicates normal data transmission, with no error signal returned (Initial value) [Clearing conditions] The chip is reset or enters standby mode. Software reads ERS while it is set to 1, then writes 0. 1 Indicates that the receiving device sent an error signal reporting a parity error [Setting condition] A low error signal was sampled. Note: Clearing the TE bit to 0 in SCR does not affect the ERS flag, which retains its previous value. Bits 3 to 0: These bits operate as in normal serial communication. For details see section 13, Serial Communication Interface. The setting conditions for transmit end (TEND, bit 2), however, are modified as follows. Bit 2: TEND 0 Description Transmission is in progress [Clearing conditions] Software reads TDRE while it is set to 1, then writes 0 in the TDRE flag. The DMAC writes data in TDR. 1 End of transmission [Setting conditions] The chip is reset or enters standby mode. The TE bit and FER/ERS bit are both cleared to 0 in SCR. TDRE is 1 and FER/ERS is 0 at a time 2.5 etu after the last bit of a 1-byte serial character is transmitted (normal transmission) Note: An etu (elementary time unit) is the time needed to transmit one bit. (Initial value) Rev. 2.0, 03/01, page 504 of 822 14.2.3 Serial Mode Register (SMR) Bit 7 of SMR has a different function in smart card interface mode. The related serial control register (SCR) changes from bit 1 to bit 0. Bit Initial value Read/Write 7 GM 0 R/W 6 CHR 0 R/W 5 PR 0 R/W 4 O/E 0 R/W 3 STOP 0 R/W 2 MP 0 R/W 1 CKS1 0 R/W 0 CKS0 0 R/W Bit 7--GSM Mode (GM): Set at 0 when using the regular smart card interface. In GSM mode, set to 1. When transmission is complete, initially the TEND flag set timing appears followed by clock output restriction mode. Clock output restriction mode comprises serial control register bit 1 and bit 0. Bit 7: GM 0 Description Using the regular smart card interface mode The TEND flag is set 12.5 etu after the beginning of the start bit Clock output on/off control only 1 Using the GSM mode smart card interface mode The TEND flag is set 11.0 etu after the beginning of the start bit Clock output on/off and fixed-high/fixed-low control (set in SCR) (Initial value) Bits 6 to 0--Operate in the same way as for the normal SCI. For details, see section 13.2.5, Serial Mode Register (SMR). Rev. 2.0, 03/01, page 505 of 822 14.2.4 Serial Control Register (SCR) Bits 1 and 0 have different functions in smart card interface mode. Bit Initial value Read/Write 7 TIE 0 R/W 6 RIE 0 R/W 5 TE 0 R/W 4 RE 0 R/W 3 MPIE 0 R/W 2 TEIE 0 R/W 1 CKE1 0 R/W 0 CKE0 0 R/W Bits 7 to 2--Operate in the same way as for the normal SCI. For details, see section 13.2.6, Serial Control Register (SCR). Bits 1 and 0--Clock Enable (CKE1, CKE0): Setting enable or disable for the SCI clock selection and clock output from the SCK pin. In smart card interface mode, it is possible to switch between enabling and disabling of the normal clock output, and specify a fixed high level or fixed low level for the clock output. SMR Bit 7: GM 0 0 1 1 1 1 Bit 1: CKE1 0 0 0 0 1 1 SCR Bit 0: CKE0 0 1 0 1 0 1 Description The internal clock/SCK0 pin functions as an I/O port (Initial value) The internal clock/SCK0 pin functions as the clock output The internal clock/SCK0 pin is fixed at low-level output The internal clock/SCK0 pin functions as the clock output The internal clock/SCK0 pin is fixed at high-level output The internal clock/SCK0 pin functions as the clock output Rev. 2.0, 03/01, page 506 of 822 14.3 14.3.1 Operation Overview The main features of the smart-card interface are as follows. * One frame consists of eight data bits and a parity bit. * In transmitting, a guard time of at least two elementary time units (2 etu) is provided between the end of the parity bit and the start of the next frame. (An elementary time unit is the time required to transmit one bit.) * In receiving, if a parity error is detected, a low error signal is output for 1 etu, beginning 10.5 etu after the start bit. * In transmitting, if an error signal is received, after at least 2 etu, the same data is automatically transmitted again. * Only asynchronous communication is supported. There is no synchronous communication function. 14.3.2 Pin Connections Figure 14.2 shows a pin connection diagram for the smart card interface. In communication with a smart card, data is transmitted and received over the same signal line. The TxD0 and RxD0 pins should both be connected to this line. The data transmission line should be pulled up to VCC through a resistor. If the smart card uses the clock generated by the smart card interface, connect the SCK0 output pin to the card's CLK input. If the card uses its own internal clock, this connection is unnecessary. The reset signal should be output from one of the H8/3052F' generic ports. In addition to these pin connections, power and ground connections will normally also be necessary. Rev. 2.0, 03/01, page 507 of 822 VCC TxD0 RxD0 SCK0 Clock line Px (port) H8/3052F Chip Card-processing device Reset line Data line I/O CLK RST Smart card Figure 14.2 Smart Card Interface Connection Diagram Note: A loop-back test can be performed by setting both RE and TE to 1 without connecting a smart card. Rev. 2.0, 03/01, page 508 of 822 14.3.3 Data Format Figure 14.3 shows the data format of the smart card interface. In receive mode, parity is checked once per frame. If a parity error is detected, an error signal is returned to the transmitting device to request retransmission. In transmit mode, the error signal is sampled and the same data is retransmitted if the error signal is low. No parity error Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp Output from transmitting device Parity error Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp DE Output from transmitting device Output from receiving device Ds: D0 to D7: Dp: DE: Start bit Data bits Parity bit Error signal Figure 14.3 Smart Card Interface Data Format The operating sequence is as follows. 1. When not in use, the data line is in the high-impedance state, and is pulled up to the high level through a resistor. 2. To start transmitting a frame of data, the transmitting device transmits a low start bit (Ds), followed by eight data bits (D0 to D7) and a parity bit (Dp). 3. Next, in the smart card interface, the transmitting device returns the data line to the highimpedance state. The data line is pulled up to the high level through a resistor. 4. The receiving device performs a parity check. If there is no parity error, the receiving device waits to receive the next data. If a parity error is present, the receiving device outputs a low error signal (DE) to request retransmission of the data. After outputting the error signal for a designated interval, the receiving device returns the signal line to the high-impedance state. The signal line is pulled back up to the high level through the pull-up resistor. 5. If the transmitting device does not receive an error signal, it proceeds to transmit the next data. If it receives an error signal, it returns to step 2 and transmits the same data again. Rev. 2.0, 03/01, page 509 of 822 14.3.4 Register Settings Table 14.3 shows a bit map of the registers used in the smart card interface. Bits indicated as 0 or 1 should always be set to the indicated value. The settings of the other bits will be described in this section. Table 14.3 Register Settings in Smart Card Interface Register SMR BRR SCR TDR SSR RDR SCMR Address* H'FFB0 H'FFB1 H'FFB2 H'FFB3 H'FFB4 H'FFB5 H'FFB6 1 Bit 7 GM BRR7 TIE TDR7 TDRE RDR7 -- Bit 6 0 BRR6 RIE TDR6 RDRF RDR6 -- Bit 5 1 BRR5 TE TDR5 ORER RDR5 -- Bit 4 O/E BRR4 RE TDR4 ERS RDR4 -- Bit 3 1 BRR3 0 TDR3 PER RDR3 SDIR Bit 2 0 BRR2 0 TDR2 TEND RDR2 SINV Bit 1 CKS1 BRR1 2 Bit 0 CKS0 BRR0 TDR0 0 RDR0 SMIF CKE1* CKE0 TDR1 0 RDR1 -- Notes: -- Unused bit. 1. Lower 16 bits of the address. 2. When the GM of the SMR is set at 0, be sure the CKE1 bit is 0. Serial Mode Register (SMR) Settings: In regular smart card interface mode, set the GM bit at 0. In regular smart card mode, clear the GM bit to 0. In GSM mode, set the GM bit to 1. Clear the O/( bit to 0 if the smart card uses the direct convention. Set the O/( bit to 1 if the smart card uses the inverse convention. Bits CKS1 and CKS0 select the clock source of the built-in baud rate generator. See section 14.3.5, Clock. Bit Rate Register (BRR) Settings: This register sets the bit rate. Equations for calculating the setting are given in section 14.3.5, Clock. Serial Control Register (SCR): The TIE, RIE, TE, and RE bits have their normal serial communication functions. For details, see section 13, Serial Communication Interface. The CKE1 and CKE0 bits select clock output. When the GM bit of the SMR is cleared to 0, to disable clock output, clear this bit to 00. To enable clock output, set this bit to 01. When the GM bit of the SMR is set to 1, clock output is enabled. Clock output is fixed at high or low. Smart Card Mode Register (SCMR): If the smart card follows the direct convention, clear the SDIR and SINV bits to 0. If the smart card follows the indirect convention, set the SDIR and SINV bits to 1. To use the smart card interface, set the SMIF bit to 1. Rev. 2.0, 03/01, page 510 of 822 The register settings and examples of starting character waveforms are shown below for two smart cards, one following the direct convention and one the inverse convention. * Direct convention (SDIR = SINV = O/( = 0) (Z) A Z Z A Z Z Z A A Z (Z) State Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp In the direct convention, state Z corresponds to logic level 1, and state A to logic level 0. Characters are transmitted and received LSB-first. In the example above the first character data is H'3B. The parity bit is 1, following the even parity rule designated for smart cards. * Inverse convention (SDIR = SINV = O/( = 1) (Z) A Z Z A A A A A A Z (Z) State Ds D7 D6 D5 D4 D3 D2 D1 D0 Dp In the inverse convention, state A corresponds to the logic level 1, and state Z to the logic level 0. Characters are transmitted and received MSB-first. In the example above the first character data is H'3F. Following the even parity rule designated for smart cards, the parity bit logic level is 0, corresponding to state Z. In the H8/3052F, the SINV bit inverts only the data bits D7 to D0. The parity bit is not inverted, so the O/( bit in SMR must be set to odd parity mode. This applies in both transmitting and receiving. Rev. 2.0, 03/01, page 511 of 822 14.3.5 Clock As its serial communication clock, the smart card interface can use only the internal clock generated by the on-chip baud rate generator. The bit rate can be selected by setting the bit rate register (BRR) and bits CKS1 and CKS0 in the serial mode register (SMR). The bit rate can be calculated from the equation given below. Table 14.5 lists some examples of bit rate settings. If bit CKE0 is set to 1, a clock signal with a frequency equal to 372 times the bit rate is output from the SCK0 pin. B= 1488 x 22n-1 x (N + 1) x 106 where, N: B: : n: BRR setting (0 N 255) Bit rate (bits/s) System clock frequency (MHz)* See table 14.4 Table 14.4 n-Values of CKS1 and CKS0 Settings n 0 1 2 3 CKS1 0 0 1 1 CKS0 0 1 0 1 Note: * If the gear function is used to divide the system clock frequency, use the divided frequency to calculate the bit rate. The equation above applies directly to 1/1 frequency division. Table 14.5 Bit Rates (bits/s) for Different BRR Settings (when n = 0) (MHz) N 0 1 2 7.1424 9600.0 4800.0 3200.0 10.00 10.7136 13.00 14.2848 16.00 18.00 20.00 25.00 13440.9 14400.0 17473.1 19200.0 21505.4 24193.5 26881.7 33602.2 6720.4 4480.3 7200.0 4800.0 8736.6 5824.4 9600.0 6400.0 10752.7 12096.8 13440.9 16801.1 7168.5 8064.5 8960.6 11200.7 Note: Bit rates are rounded off to one decimal place. Rev. 2.0, 03/01, page 512 of 822 The following equation calculates the bit rate register (BRR) setting from the system clock frequency and bit rate. N is an integer from 0 to 255, specifying the value with the smaller error. N= 1488 x 22n-1 x B x 106 - 1 Table 14.6 BRR Settings for Typical Bit Rate (bits/s) (when n = 0) (MHz) 7.1424 Bit/s 9600 N Error 0 0.00 10.00 N Error 10.7136 N Error 13.00 N Error 14.2848 N Error 1 0.00 16.00 N Error 18.00 N Error 20.00 N Error 25.00 N Error 3 12.49 1 30.00 1 25.00 1 8.99 1 12.01 2 15.99 2 6.66 Table 14.7 Maximum Bit Rates for Various Frequencies (Smart Card Interface) (MHz) 7.1424 10 10.7136 13 14.2848 16 18 20 25 Maximum Bit Rate (bits/s) 9600 13441 14400 17473 19200 21505 24194 26882 33602 N 0 0 0 0 0 0 0 0 0 n 0 0 0 0 0 0 0 0 0 The bit rate error is calculated from the following equation. Error (%) = 1488 x 22n-1 x B x (N + 1) x 106 - 1 x 100 Rev. 2.0, 03/01, page 513 of 822 14.3.6 Transmitting and Receiving Data Initialization: Before transmitting or receiving data, initialize the smart card interface by the procedure below. Initialization is also necessary when switching from transmit mode to receive mode or from receive mode to transmit mode. 1. Clear the TE and RE bits to 0 in the serial control register (SCR). 2. Clear the ERS, PER, and ORER error flags to 0 in the serial status register (SSR). 3. Set the parity mode bit (O/() and baud rate generator clock source select bits (CKS1 and CKS0) as required in the serial mode register (SMR). At the same time, clear the C/$, CHR, and MP bits to 0, and set the STOP and PE bits to 1. 4. Set the SMIF, SDIR, and SINV bits as required in the smart card mode register (SMR). When the SMIF bit is set to 1, the TxD0 and RxD0 pins switch from their I/O port functions to their serial communication interface functions, and are placed in the high-impedance state. 5. Set a value corresponding to the desired bit rate in the bit rate register (BRR). 6. Set clock enable bit 0 (CKE0) as required in the serial control register (SCR). Write 0 in the TIE, RIE, TE, RE, MPIE, TEIE, and CKE1 bits. If bit CKE0 is set to 1, a serial clock will be output from the SCK0 pin. 7. Wait for at least the interval required to transmit or receive one bit, then set the TIE, RIE, TE, and RE bits as necessary in SCR. Do not set TE and RE both to 1, except when performing a loop-back test. Transmitting Serial Data: The transmitting procedure in smart card mode is different from the normal SCI procedure, because of the need to sample the error signal and retransmit. Figure 14.4 shows a flowchart for transmitting, and figure 14.5 shows the relation between a transmit operation and the internal registers. 1. Initialize the smart card interface by the procedure given above in Initialization. 2. Check that the ERS error flag is cleared to 0 in SSR. 3. Check that the TEND flag is set to 1 in SSR. Repeat steps 2 and 3 until this check passes. 4. Write transmit data in TDR and clear the TDRE flag to 0. The data will be transmitted and the TEND flag will be cleared to 0. 5. To continue transmitting data, return to step 2. 6. To terminate transmission, clear the TE bit to 0. This procedure may include interrupt handling and DMA transfer. If the TIE bit is set to 1 to enable interrupt requests, when transmission is completed and the TEND flag is set to 1, a transmit-data-empty interrupt (TXI) is requested. If the RIE bit is set to 1 to enable interrupt requests, when a transmit error occurs and the ERS flag is set to 1, a transmit/receive-error interrupt (ERI) is requested. Rev. 2.0, 03/01, page 514 of 822 The timing of TEND flag setting depends on the GM bit in SMR. The timing is shown in figure 14.6. If the TXI interrupt activates the DMAC, the number of bytes designated in the DMAC can be transmitted automatically, including automatic retransmit. For details, see Interrupt Operations and Data Transfer by DMAC in this section. Start Initialize Start transmitting No FER/ERS = 0 ? Yes Error handling No TEND = 1 ? Yes Write data in TDR and clear TDRE flag to 0 in SSR No All data transmitted ? Yes FER/ERS = 0 ? Yes No Error handling No TEND = 1 ? Yes Clear TE bit to 0 End Figure 14.4 Transmit Flowchart (Example) Rev. 2.0, 03/01, page 515 of 822 TDR (1) Data write (2) Transfer from TDR to TSR (3) Serial data output Data 1 Data 1 Data 1 TSR (shift register) Data 1 ; Data remains in TDR Data 1 I/O signal line output In case of normal transmission: TEND flag is set In case of transmit error: ERS flag is set Steps (2) and (3) above are repeated until the TEND flag is set Note: When the ERS flag is set, it should be cleared until transfer of the last bit (D7 in LSB-first transmission, D0 in MSB-first transmission) of the next transfer data to be transmitted has been completed. Figure 14.5 Relation Between Transmit Operation and Internal Registers I/O data DS Da Db Dc Dd De Df Dg Dh Dp DE Guard TXI (TEND interrupt) 12.5 etu GM = 0 11.0 etu GM = 1 Figure 14.6 TEND Flag Occurrence Timing Rev. 2.0, 03/01, page 516 of 822 Receiving Serial Data: The receiving procedure in smart card mode is the same as the normal SCI procedure. Figure 14.7 shows a flowchart for receiving. 1. Initialize the smart card interface by the procedure given in Initialization at the beginning of this section. 2. Check that the ORER and PER error flags are cleared to 0 in SSR. If either flag is set, carry out the necessary error handling, then clear both the ORER and PER flags to 0. 3. Check that the RDRF flag is set to 1. Repeat steps 2 and 3 until this check passes. 4. Read receive data from RDR. 5. To continue receiving data, clear the RDRF flag to 0 and return to step 2. 6. To terminate receiving, clear the RE bit to 0. Start Initialize Start receiving ORER = 0 and PER = 0 ? Yes No Error handling No RDRF = 1 ? Yes Read RDR and clear RDRF flag to 0 in SSR No All data received ? Clear RE bit to 0 Figure 14.7 Receive Flowchart (Example) Rev. 2.0, 03/01, page 517 of 822 This procedure may include interrupt handling and DMA transfer. If the RIE bit is set to 1 to enable interrupt requests, when receiving is completed and the RDRF flag is set to 1, a receive-data-full interrupt (RXI) is requested. If a receive error occurs, either the ORER or PER flag is set to 1 and a transmit/receive-error interrupt (ERI) is requested. If the RXI interrupt activates the DMAC, the number of bytes designated in the DMAC will be transferred, skipping receive data in which an error occurred. For details, see Interrupt Operations and Data Transfer by DMAC below. When a parity error occurs and PER is set to 1, the receive data is transferred to RDR, so the erroneous data can be read. Switching Modes: To switch from receive mode to transmit mode, check that receiving operations have completed, then initialize the smart card interface, clearing RE to 0 and setting TE to 1. Completion of receive operations is indicated by the RDRF, PER, or ORER flag. To switch from transmit mode to receive mode, check that transmitting operations have completed, then initialize the smart card interface, clearing TE to 0 and setting RE to 1. Completion of transmit operations can be verified from the TEND flag. Fixing Clock Output: When the GM bit of the SMR is set to 1, clock output is fixed by CKE1 and CKE0 of SCR. In this case, the clock pulse can be set at minimum value. Figure 14.8 shows clock output fixed timing: CKE0 is restricted with GM = 1 and CKE1 = 1. Specified pulse width CKE1 value Specified pulse width SCK SCR write (CKE0 = 0) SCR write (CKE0 = 1) Figure 14.8 Clock Output Fixed Timing Rev. 2.0, 03/01, page 518 of 822 Interrupt Operations: The smart card interface has three interrupt sources: transmit-data-empty (TXI), transmit/receive-error (ERI), and receive-data-full (RXI). The transmit-end interrupt request (TEI) is not available in smart card mode. A TXI interrupt is requested when the TEND flag is set to 1 in SSR. An RXI interrupt is requested when the RDRF flag is set to 1 in SSR. An ERI interrupt is requested when the ORER, PER, or ERS flag is set to 1 in SSR. These relationships are shown in table 14.8. Table 14.8 Smart Card Mode Operating States and Interrupt Sources Operating State Transmit mode Receive mode Normal operation Error Normal operation Error Flag TEND ERS RDRF PER, ORER Mask Bit TIE RIE RIE RIE Interrupt Source TXI ERI RXI ERI DMAC Activation Available Not available Available Not available Data Transfer by DMAC: The DMAC can be used to transmit and receive in smart card mode, as in normal SCI operations. In transmit mode, when the TEND flag is set to 1 in SSR, the TDRE flag is set simultaneously, generating a TXI interrupt. If TXI is designated in advance as a DMAC activation source, the DMAC will be activated by the TXI request and will transfer the next transmit data. This data transfer by the DMAC automatically clears the TDRE and TEND flags to 0. When an error occurs, the SCI automatically retransmits the same data, keeping TEND cleared to 0 so that the DMAC is not activated. The SCI and DMAC will therefore automatically transmit the designated number of bytes, including retransmission when an error occurs. When an error occurs the ERS flag is not cleared automatically, so the RIE bit should be set to 1 to enable the error to generate an ERI request, and the ERI interrupt handler should clear ERS. When using the DMAC to transmit or receive, first set up and enable the DMAC, then make SCI settings. DMAC settings are described in section 8, DMA Controller. In receive operations, when the RDRF flag is set to 1 in SSR, an RXI interrupt is requested. If RXI is designated in advance as a DMAC activation source, the DMAC will be activated by the RXI request and will transfer the received data. This data transfer by the DMAC automatically clears the RDRF flag to 0. When an error occurs, the RDRF flag is not set and an error flag is set instead. The DMAC is not activated. The ERI interrupt request is directed to the CPU. The ERI interrupt handler should clear the error flags. Rev. 2.0, 03/01, page 519 of 822 Examples of Operation in GSM Mode: When switching between smart card interface mode and software standby mode, use the following procedures to maintain the clock duty cycle. * Switching from smart card interface mode to software standby mode 1. Set the P94 data register (DR) and data direction register (DDR) to the values for the fixed output state in software standby mode. 2. Write 0 to the TE and RE bits in the serial control register (SCR) to stop transmit/receive operations. At the same time, set the CKE1 bit to the value for the fixed output state in software standby mode. 3. Write 0 to the CKE0 bit in SCR to stop the clock. 4. Wait for one serial clock cycle. During this period, the duty cycle is preserved and clock output is fixed at the specified level. 5. Write H'00 to the serial mode register (SMR) and smart card mode register (SCMR). 6. Make the transition to the software standby state. * Returning from software standby mode to smart card interface mode 1. Clear the software standby state. 2. Set the CKE1 bit in SCR to the value for the fixed output state at the start of software standby (the current P94 pin state). 3. Set smart card interface mode and output the clock. Clock signal generation is started with the normal duty cycle. Normal operation Software standby mode Normal operation (1)(2)(3) (4) (5)(6) (1) (2)(3) Figure 14.9 Procedure for Stopping and Restarting the Clock Use the following procedure to secure the clock duty cycle after powering on. 1. The initial state is port input and high impedance. Use pull-up or pull-down resistors to fix the potential. 2. Fix at the output specified by the CKE1 bit in SCR. 3. Set SMR and SCMR, and switch to smart card interface mode operation. 4. Set the CKE0 bit in SCR to 1 to start clock output. Rev. 2.0, 03/01, page 520 of 822 14.4 Usage Notes When using the SCI as a smart card interface, note the following points. Receive Data Sampling Timing in Smart Card Mode and Receive Margin: In smart card mode the SCI operates on a base clock with 372 times the bit rate frequency. In receiving, the SCI synchronizes internally with the fall of the start bit, which it samples on the base clock. Receive data is latched at the rising edge of the 186th base clock pulse. See figure 14.10. 372 clocks 186 clocks 0 185 371 0 185 371 0 Internal base clock Receive data (RxD) Start bit D0 D1 Synchronization sampling timing Data sampling timing Figure 14.10 Receive Data Sampling Timing in Smart Card Mode Rev. 2.0, 03/01, page 521 of 822 The receive margin can therefore be expressed as follows. Receive margin in smart card mode: M= 0.5 - 1 2N - (L - 0.5) F - D - 0.5 N (1 + F) x 100% M: Receive margin (%) N: Ratio of clock frequency to bit rate (N = 372) D: Clock duty cycle (D = 0 to 1.0) L: Frame length (L = 10) F: Absolute deviation of clock frequency From this equation, if F = 0 and D = 0.5 the receive margin is as follows. D = 0.5, F = 0 M = {0.5 - 1/(2 x 372)} x 100% = 49.866% Rev. 2.0, 03/01, page 522 of 822 Retransmission: Retransmission is described below for the separate cases of transmit mode and receive mode. * Retransmission when SCI is in Receive Mode (See Figure 14.11) 1. The SCI checks the received parity bit. If it detects an error, it automatically sets the PER flag to 1. If the RIE bit in SCR is set to the enable state, an ERI interrupt is requested. The PER flag should be cleared to 0 in SSR before the next parity bit sampling timing. 2. The RDRF bit in SSR is not set to 1 for the error frame. 3. If an error is not detected when the parity bit is checked, the PER flag is not set in SSR. 4. If an error is not detected when the parity bit is checked, receiving operations are assumed to have ended normally, and the RDRF bit is automatically set to 1 in SSR. If the RIE bit in SCR is set to the enable state, an RXI interrupt is requested. If RXI is enabled as a DMA transfer activation source, the RDR contents can be read automatically. When the DMAC reads the RDR data, it automatically clears RDRF to 0. 5. When a normal frame is received, at the error signal transmit timing, the data pin is held in the high-impedance state. Frame n Retransmitted frame (DE) Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp DE Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp Ds D0 D1 D2 D3 D4 Frame n + 1 RDRF (2) PER (1) (3) (4) Figure 14.11 Retransmission in SCI Receive Mode Rev. 2.0, 03/01, page 523 of 822 * Retransmission when SCI is in Transmit Mode (See Figure 14.12) 6. After transmitting one frame, if the receiving device returns an error signal, the SCI sets the ERS flag to 1 in SSR. If the RIE bit in SCR is set to the enable state, an ERI interrupt is requested. The ERS flag should be cleared to 0 in SSR before the next parity bit sampling timing. 7. The TEND bit in SSR is not set for the frame in which the error signal was received, indicating an error. 8. If no error signal is returned from the receiving device, the ERS flag is not set in SSR. 9. If no error signal is returned from the receiving device, transmission of the frame, including retransmission, is assumed to be complete, and the TEND bit is set to 1 in SSR. If the TIE bit in SCR is set to the enable state, a TXI interrupt is requested. If TXI is enabled as a DMA transfer activation source, the next data can be written in TDR automatically. When the DMAC writes data in TDR, it automatically clears the TDRE bit to 0. Frame n Retransmitted frame (DE) Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp DE Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp Ds D0 D1 D2 D3 D4 Frame n + 1 TDRE Transfer from TDR to TSR TEND (7) ERS (6) (8) (9) Transfer from TDR to TSR Transfer from TDR to TSR Figure 14.12 Retransmission in SCI Transmit Mode Rev. 2.0, 03/01, page 524 of 822 Section 15 A/D Converter 15.1 Overview The H8/3052F includes a 10-bit successive-approximations A/D converter with a selection of up to eight analog input channels. When the A/D converter is not used, it can be halted independently to conserve power. For details see section 20.6, Module Standby Function. 15.1.1 Features A/D converter features are listed below. * 10-bit resolution * Eight input channels * Selectable analog conversion voltage range The analog voltage conversion range can be programmed by input of an analog reference voltage at the VREF pin. * High-speed conversion Conversion time: maximum 5.4 s per channel (with 25 MHz system clock) * Two conversion modes Single mode: A/D conversion of one channel Scan mode: continuous conversion on one to four channels * Four 16-bit data registers A/D conversion results are transferred for storage into data registers corresponding to the channels. * Sample-and-hold function * A/D conversion can be externally triggered * A/D interrupt requested at end of conversion At the end of A/D conversion, an A/D end interrupt (ADI) can be requested. Rev. 2.0, 03/01, page 525 of 822 15.1.2 Block Diagram Figure 15.1 shows a block diagram of the A/D converter. Module data bus Bus interface ADDRC ADDRD ADDRA ADDRB ADCSR Internal data bus AVCC V REF AV SS 10-bit D/A Successiveapproximations register AN 0 AN 1 AN 2 AN 3 AN 4 AN 5 AN 6 AN 7 Analog multiplexer + - Comparator Control circuit Sample-andhold circuit /16 /8 ADCR ADTRG Legend ADCR: ADCSR: ADDRA: ADDRB: ADDRC: ADDRD: ADI interrupt signal A/D control register A/D control/status register A/D data register A A/D data register B A/D data register C A/D data register D Figure 15.1 A/D Converter Block Diagram Rev. 2.0, 03/01, page 526 of 822 15.1.3 Pin Configuration Table 15.1 summarizes the A/D converter's input pins. The eight analog input pins are divided into two groups: group 0 (AN0 to AN3), and group 1 (AN4 to AN7). AVCC and AVSS are the power supply for the analog circuits in the A/D converter. VREF is the A/D conversion reference voltage. Table 15.1 A/D Converter Pins Pin Name Analog power supply pin Analog ground pin Reference voltage pin Analog input pin 0 Analog input pin 1 Analog input pin 2 Analog input pin 3 Analog input pin 4 Analog input pin 5 Analog input pin 6 Analog input pin 7 A/D external trigger input pin Abbreviation AVCC AVSS VREF AN0 AN1 AN2 AN3 AN4 AN5 AN6 AN7 $'75* I/O Input Input Input Input Input Input Input Input Input Input Input Input External trigger input for starting A/D conversion Group 1 analog inputs Function Analog power supply Analog ground and reference voltage Analog reference voltage Group 0 analog inputs Rev. 2.0, 03/01, page 527 of 822 15.1.4 Register Configuration Table 15.2 summarizes the A/D converter's registers. Table 15.2 A/D Converter Registers Address* H'FFE0 H'FFE1 H'FFE2 H'FFE3 H'FFE4 H'FFE5 H'FFE6 H'FFE7 H'FFE8 H'FFE9 1 Name A/D data register A (high) A/D data register A (low) A/D data register B (high) A/D data register B (low) A/D data register C (high) A/D data register C (low) A/D data register D (high) A/D data register D (low) A/D control/status register A/D control register Abbreviation ADDRAH ADDRAL ADDRBH ADDRBL ADDRCH ADDRCL ADDRDH ADDRDL ADCSR ADCR R/W R R R R R R R R R/(W)* R/W 2 Initial Value H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'00 H'7E Notes: 1. Lower 16 bits of the address 2. Only 0 can be written in bit 7, to clear the flag. Rev. 2.0, 03/01, page 528 of 822 15.2 15.2.1 Bit ADDRn Register Descriptions A/D Data Registers A to D (ADDRA to ADDRD) 15 0 R 14 0 R 13 0 R 12 0 R 11 0 R 10 0 R 9 0 R 8 0 R 7 0 R 6 0 R 5 0 R 4 -- 0 R 3 -- 0 R 2 -- 0 R 1 -- 0 R 0 -- 0 R AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 -- Initial value Read/Write (n = A to D) A/D conversion data 10-bit data giving an A/D conversion result Reserved bits The four A/D data registers (ADDRA to ADDRD) are 16-bit read-only registers that store the results of A/D conversion. An A/D conversion produces 10-bit data, which is transferred for storage into the A/D data register corresponding to the selected channel. The upper 8 bits of the result are stored in the upper byte of the A/D data register. The lower 2 bits are stored in the lower byte. Bits 5 to 0 of an A/D data register are reserved bits that are always read as 0. Table 15.3 indicates the pairings of analog input channels and A/D data registers. The CPU can always read and write the A/D data registers. The upper byte can be read directly, but the lower byte is read through a temporary register (TEMP). For details see section 15.3, CPU Interface. The A/D data registers are initialized to H'0000 by a reset and in standby mode. Table 15.3 Analog Input Channels and A/D Data Registers Analog Input Channel Group 0 AN0 AN1 AN2 AN3 Group 1 AN4 AN5 AN6 AN7 A/D Data Register ADDRA ADDRB ADDRC ADDRD Rev. 2.0, 03/01, page 529 of 822 15.2.2 Bit A/D Control/Status Register (ADCSR) 7 ADF 0 R/(W)* 6 ADIE 0 R/W 5 ADST 0 R/W 4 SCAN 0 R/W 3 CKS 0 R/W 2 CH2 0 R/W 1 CH1 0 R/W 0 CH0 0 R/W Initial value Read/Write Channel select 2 to 0 These bits select analog input channels Clock select Selects the A/D conversion time Scan mode Selects single mode or scan mode A/D start Starts or stops A/D conversion A/D interrupt enable Enables and disables A/D end interrupts A/D end flag Indicates end of A/D conversion Note: * Only 0 can be written, to clear the flag. ADCSR is an 8-bit readable/writable register that selects the mode and controls the A/D converter. ADCSR is initialized to H'00 by a reset and in standby mode. Bit 7--A/D End Flag (ADF): Indicates the end of A/D conversion. Bit 7: ADF 0 1 Description [Clearing condition] Cleared by reading ADF while ADF = 1, then writing 0 in ADF [Setting conditions] Single mode: A/D conversion ends Scan mode: A/D conversion ends in all selected channels (Initial value) Rev. 2.0, 03/01, page 530 of 822 Bit 6--A/D Interrupt Enable (ADIE): Enables or disables the interrupt (ADI) requested at the end of A/D conversion. Bit 6: ADIE 0 1 Description A/D end interrupt request (ADI) is disabled A/D end interrupt request (ADI) is enabled (Initial value) Bit 5--A/D Start (ADST): Starts or stops A/D conversion. The ADST bit remains set to 1 during A/D conversion. It can also be set to 1 by external trigger input at the $'75* pin. Bit 5: ADST 0 1 Description A/D conversion is stopped (Initial value) Single mode: A/D conversion starts; ADST is automatically cleared to 0 when conversion ends. Scan mode: A/D conversion starts and continues, cycling among the selected channels, until ADST is cleared to 0 by software, by a reset, or by a transition to standby mode. Bit 4--Scan Mode (SCAN): Selects single mode or scan mode. For further information on operation in these modes, see section 15.4, Operation. Clear the ADST bit to 0 before switching the conversion mode. Bit 4: SCAN 0 1 Description Single mode Scan mode (Initial value) Bit 3--Clock Select (CKS): Selects the A/D conversion time. Clear the ADST bit to 0 before switching the conversion time. Bit 3: CKS 0 1 Description Conversion time = 266 states (maximum) Conversion time = 134 states (maximum) (Initial value) Rev. 2.0, 03/01, page 531 of 822 Bits 2 to 0--Channel Select 2 to 0 (CH2 to CH0): These bits and the SCAN bit select the analog input channels. Clear the ADST bit to 0 before changing the channel selection. Group Selection CH2 0 Channel Selection CH1 0 1 CH0 0 1 0 1 0 1 1 0 1 Single Mode AN0 (Initial value) AN1 AN2 AN3 AN4 AN5 AN6 AN7 Description Scan Mode AN0 AN0, AN1 AN0 to AN2 AN0 to AN3 AN4 AN4, AN5 AN4 to AN6 AN4 to AN7 1 0 15.2.3 Bit A/D Control Register (ADCR) 7 TRGE 0 R/W 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 0 -- Initial value Read/Write Reserved bits Trigger enable Enables or disables external triggering of A/D conversion Reserved bit Must not be set to 1 ADCR is an 8-bit readable/writable register that enables or disables external triggering of A/D conversion. ADCR is initialized to H'7E by a reset and in standby mode. Bit 7--Trigger Enable (TRGE): Enables or disables external triggering of A/D conversion. Bit 7: TRGE 0 1 Description A/D conversion cannot be externally triggered (Initial value) A/D conversion starts at the falling edge of the external trigger signal ($'75*) Bits 6 to 1--Reserved: Read-only bits, always read as 1. Bit 0--Reserved: Do not set to 1. Rev. 2.0, 03/01, page 532 of 822 15.3 CPU Interface ADDRA to ADDRD are 16-bit registers, but they are connected to the CPU by an 8-bit data bus. Therefore, although the upper byte can be be accessed directly by the CPU, the lower byte is read through an 8-bit temporary register (TEMP). An A/D data register is read as follows. When the upper byte is read, the upper-byte value is transferred directly to the CPU and the lower-byte value is transferred into TEMP. Next, when the lower byte is read, the TEMP contents are transferred to the CPU. When reading an A/D data register, always read the upper byte before the lower byte. It is possible to read only the upper byte, but if only the lower byte is read, incorrect data may be obtained. Figure 15.2 shows the data flow for access to an A/D data register. Upper-byte read CPU (H'AA) Module data bus Bus interface TEMP (H'40) ADDRnH (H'AA) ADDRnL (H'40) (n = A to D) Lower-byte read CPU (H'40) Module data bus Bus interface TEMP (H'40) ADDRnH (H'AA) ADDRnL (H'40) (n = A to D) Figure 15.2 A/D Data Register Access Operation (Reading H'AA40) Rev. 2.0, 03/01, page 533 of 822 15.4 Operation The A/D converter operates by successive approximations with 10-bit resolution. It has two operating modes: single mode and scan mode. 15.4.1 Single Mode (SCAN = 0) Single mode should be selected when only one A/D conversion on one channel is required. A/D conversion starts when the ADST bit is set to 1 by software, or by external trigger input. The ADST bit remains set to 1 during A/D conversion and is automatically cleared to 0 when conversion ends. When conversion ends the ADF bit is set to 1. If the ADIE bit is also set to 1, an ADI interrupt is requested at this time. To clear the ADF flag to 0, first read ADCSR, then write 0 in ADF. When the mode or analog input channel must be switched during analog conversion, to prevent incorrect operation, first clear the ADST bit to 0 in ADCSR to halt A/D conversion. After making the necessary changes, set the ADST bit to 1 to start A/D conversion again. The ADST bit can be set at the same time as the mode or channel is changed. Typical operations when channel 1 (AN1) is selected in single mode are described next. Figure 15.3 shows a timing diagram for this example. 1. Single mode is selected (SCAN = 0), input channel AN1 is selected (CH2 = CH1 = 0, CH0 = 1), the A/D interrupt is enabled (ADIE = 1), and A/D conversion is started (ADST = 1). 2. When A/D conversion is completed, the result is transferred into ADDRB. At the same time the ADF flag is set to 1, the ADST bit is cleared to 0, and the A/D converter becomes idle. 3. Since ADF = 1 and ADIE = 1, an ADI interrupt is requested. 4. The A/D interrupt handling routine starts. 5. The routine reads ADCSR, then writes 0 in the ADF flag. 6. The routine reads and processes the conversion result (ADDRB). 7. Execution of the A/D interrupt handling routine ends. After that, if the ADST bit is set to 1, A/D conversion starts again and steps 2 to 7 are repeated. Rev. 2.0, 03/01, page 534 of 822 Set * ADIE A/D conversion starts Clear * Set * Set * ADST Clear * ADF Idle State of channel 0 (AN 0) Idle A/D conversion (1) State of channel 1 (AN 1) Idle Idle A/D conversion (2) Idle State of channel 2 (AN 2) Idle State of channel 3 (AN 3) ADDRA Read conversion result A/D conversion result (1) Read conversion result A/D conversion result (2) ADDRB ADDRC ADDRD Figure 15.3 Example of A/D Converter Operation (Single Mode, Channel 1 Selected) Rev. 2.0, 03/01, page 535 of 822 Note: * Vertical arrows ( ) indicate instructions executed by software. 15.4.2 Scan Mode (SCAN = 1) Scan mode is useful for monitoring analog inputs in a group of one or more channels. When the ADST bit is set to 1 by software or external trigger input, A/D conversion starts on the first channel in the group (AN0 when CH2 = 0, AN4 when CH2 = 1). When two or more channels are selected, after conversion of the first channel ends, conversion of the second channel (AN1 or AN5) starts immediately. A/D conversion continues cyclically on the selected channels until the ADST bit is cleared to 0. The conversion results are transferred for storage into the A/D data registers corresponding to the channels. When the mode or analog input channel selection must be changed during analog conversion, to prevent incorrect operation, first clear the ADST bit to 0 in ADCSR to halt A/D conversion. After making the necessary changes, set the ADST bit to 1. A/D conversion will start again from the first channel in the group. The ADST bit can be set at the same time as the mode or channel selection is changed. Typical operations when three channels in group 0 (AN0 to AN2) are selected in scan mode are described next. Figure 15.4 shows a timing diagram for this example. 1. Scan mode is selected (SCAN = 1), scan group 0 is selected (CH2 = 0), analog input channels AN0 to AN2 are selected (CH1 = 1, CH0 = 0), and A/D conversion is started (ADST = 1). 2. When A/D conversion of the first channel (AN0) is completed, the result is transferred into ADDRA. Next, conversion of the second channel (AN1) starts automatically. 3. Conversion proceeds in the same way through the third channel (AN2). 4. When conversion of all selected channels (AN0 to AN2) is completed, the ADF flag is set to 1 and conversion of the first channel (AN0) starts again. If the ADIE bit is set to 1, an ADI interrupt is requested at this time. 5. Steps 2 to 4 are repeated as long as the ADST bit remains set to 1. When the ADST bit is cleared to 0, A/D conversion stops. After that, if the ADST bit is set to 1, A/D conversion starts again from the first channel (AN0). Rev. 2.0, 03/01, page 536 of 822 Continuous A/D conversion Set *1 Clear*1 ADST Clear* 1 A/D conversion time Idle A/D conversion (1) ADF Idle A/D conversion (4) Idle State of channel 0 (AN 0) Idle A/D conversion (2) Idle State of channel 1 (AN 1) Idle A/D conversion (3) A/D conversion (5)*2 Idle State of channel 2 (AN 2) Idle Transfer Idle State of channel 3 (AN 3) ADDRA A/D conversion result (1) A/D conversion result (4) ADDRB A/D conversion result (2) Figure 15.4 Example of A/D Converter Operation (Scan Mode, Channels AN0 to AN2 Selected) ADDRC A/D conversion result (3) ADDRD Rev. 2.0, 03/01, page 537 of 822 Notes: 1. Vertical arrows ( ) indicate instructions executed by software. 2. Data currently being converted is ignored. 15.4.3 Input Sampling and A/D Conversion Time The A/D converter has a built-in sample-and-hold circuit. The A/D converter samples the analog input at a time tD after the ADST bit is set to 1, then starts conversion. Figure 15.5 shows the A/D conversion timing. Table 15.4 indicates the A/D conversion time. As indicated in figure 15.5, the A/D conversion time includes tD and the input sampling time. The length of tD varies depending on the timing of the write access to ADCSR. The total conversion time therefore varies within the ranges indicated in table 15.4. In scan mode, the values given in table 15.4 apply to the first conversion. In the second and subsequent conversions the conversion time is fixed at 256 states when CKS = 0 or 128 states when CKS = 1. (1) Address bus (2) Write signal Input sampling timing ADF tD t SPL t CONV Legend ADCSR write cycle (1): ADCSR address (2): Synchronization delay tD : t SPL : Input sampling time t CONV: A/D conversion time Figure 15.5 A/D Conversion Timing Rev. 2.0, 03/01, page 538 of 822 Table 15.4 A/D Conversion Time (Single Mode) CKS = 0 Symbol Synchronization delay Input sampling time A/D conversion time tD tSPL tCONV Min 10 -- 259 Typ -- 63 -- Max 17 -- 266 Min 6 -- 131 CKS = 1 Typ -- 31 -- Max 9 -- 134 Note: Values in the table are numbers of states. 15.4.4 External Trigger Input Timing A/D conversion can be externally triggered. When the TRGE bit is set to 1 in ADCR, external trigger input is enabled at the $'75* pin. A high-to-low transition at the $'75* pin sets the ADST bit to 1 in ADCSR, starting A/D conversion. Other operations, in both single and scan modes, are the same as if the ADST bit had been set to 1 by software. Figure 15.6 shows the timing. Internal trigger signal ADST A/D conversion Figure 15.6 External Trigger Input Timing Rev. 2.0, 03/01, page 539 of 822 15.5 Interrupts The A/D converter generates an interrupt (ADI) at the end of A/D conversion. The ADI interrupt request can be enabled or disabled by the ADIE bit in ADCSR. 15.6 Usage Notes When using the A/D converter, note the following points: 1. Note on Board Design In board layout, separate the digital circuits from the analog circuits as much as possible. Particularly avoid layouts in which the signal lines of digital circuits cross or closely approach the signal lines of analog circuits. Induction and other effects may cause the analog circuits to operate incorrectly, or may adversely affect the accuracy of A/D conversion. The analog input signals (AN0 to AN7), analog reference voltage (VREF), and analog supply voltage (AVCC) must be separated from digital circuits by the analog ground (AVSS). The analog ground (AVSS) should be connected to a stable digital ground (VSS) at one point on the board. 2. Note on Noise To prevent damage from surges and other abnormal voltages at the analog input pins (AN0 to AN7) and analog reference voltage pin (VREF), connect a protection circuit like the one in figure 15.7 between AVCC and AVSS. The bypass capacitors connected to AVCC and VREF and the filter capacitors connected to AN0 to AN7 must be connected to AVSS. If filter capacitors like the ones in figure 15.7 are connected, the voltage values input to the analog input pins (AN0 to AN7) will be smoothed, which may give rise to error. Error can also occur if A/D conversion is frequently performed in scan mode so that the current that charges and discharges the capacitor in the sample-and-hold circuit of the A/D converter becomes greater than that input to the analog input pins via input impedance Rin. The circuit constants should therefore be selected carefully. Rev. 2.0, 03/01, page 540 of 822 AVCC VREF Rin *2 *1 *1 100 AN0 to AN7 0.1 F AVSS Notes: 1. Numeric values are approximate. 10 F 0.01 F 2. Rin: input impedance Figure 15.7 Example of Analog Input Protection Circuit Table 15.5 Analog Input Pin Ratings Item Analog input capacitance Allowable signal-source impedance Min -- -- Max 20 10* Unit pF k Note: * When VCC = 4.0 V to 5.5 V and 12 MHz.For details, refer to section 21, Electrical Characteristics. 10 k AN0 to AN7 To A/D converter 20 pF Note: Numeric values are approximate. Figure 15.8 Analog Input Pin Equivalent Circuit Rev. 2.0, 03/01, page 541 of 822 3. A/D Conversion Accuracy Definitions A/D conversion accuracy in the H8/3052F is defined as follows: * * Resolution Digital output code length of A/D converter Offset error Deviation from ideal A/D conversion characteristic of analog input voltage required to raise digital output from minimum voltage value 0000000000 to 0000000001 (figure 15.10) * Full-scale error Deviation from ideal A/D conversion characteristic of analog input voltage required to raise digital output from 1111111110 to 1111111111 (figure 15.10) * * Quantization error Intrinsic error of the A/D converter; 1/2 LSB (figure 15.9) Nonlinearity error Deviation from ideal A/D conversion characteristic in range from zero volts to full scale, exclusive of offset error, full-scale error, and quantization error. * Absolute accuracy Deviation of digital value from analog input value, including offset error, full-scale error, quantization error, and nonlinearity error. Rev. 2.0, 03/01, page 542 of 822 Digital output 111 110 101 100 011 010 001 000 Ideal A/D conversion characteristic Quantization error 1/8 2/8 3/8 4/8 5/8 6/8 7/8 FS Analog input voltage Figure 15.9 A/D Converter Accuracy Definitions (1) Rev. 2.0, 03/01, page 543 of 822 Digital output Full-scale error Ideal A/D conversion characteristic Nonlinearity error Actual A/D conversion characteristic FS Offset error Analog input voltage Figure 15.10 A/D Converter Accuracy Definitions (2) 4. Allowable Signal-Source Impedance The analog inputs of the H8/3052F are designed to assure accurate conversion of input signals with a signal-source impedance not exceeding 10 k. The reason for this rating is that it enables the input capacitor in the sample-and-hold circuit in the A/D converter to charge within the sampling time. If the sensor output impedance exceeds 10 k, charging may be inadequate and the accuracy of A/D conversion cannot be guaranteed. If a large external capacitor is provided in scan mode, then the internal 10-k input resistance becomes the only significant load on the input. In this case the impedance of the signal source is not a problem. A large external capacitor, however, acts as a low-pass filter. This may make it impossible to track analog signals with high dv/dt (e.g. a variation of 5 mV/s) (figure 15.11). To convert high-speed analog signals or to use scan mode, insert a low-impedance buffer. Rev. 2.0, 03/01, page 544 of 822 5. Effect on Absolute Accuracy Attaching an external capacitor creates a coupling with ground, so if there is noise on the ground line, it may degrade absolute accuracy. The capacitor must be connected to an electrically stable ground, such as AVSS. If a filter circuit is used, be careful of interference with digital signals on the same board, and make sure the circuit does not act as an antenna. H8/3052F Sensor output impedance Sensor input Up to 10 k Cin = 15 pF Equivalent circuit of A/D converter 10 k Low-pass filter C to 0.1 F 20 pF Figure 15.11 Analog Input Circuit (Example) Rev. 2.0, 03/01, page 545 of 822 Rev. 2.0, 03/01, page 546 of 822 Section 16 D/A Converter 16.1 Overview The H8/3052F includes a D/A converter with two channels. 16.1.1 Features D/A converter features are listed below. * Eight-bit resolution * Two output channels * Conversion time: maximum 10 s (with 20-pF capacitive load) * Output voltage: 0 V to VREF * D/A outputs can be sustained in software standby mode Rev. 2.0, 03/01, page 547 of 822 16.1.2 Block Diagram Figure 16.1 shows a block diagram of the D/A converter. Module data bus VREF DASTCR AVCC DADR0 DADR1 DA 0 DA 1 AVSS 8-bit D/A DACR Legend DACR: D/A control register DADR0: D/A data register 0 DADR1: D/A data register 1 DASTCR: D/A standby control register Control circuit Figure 16.1 D/A Converter Block Diagram Rev. 2.0, 03/01, page 548 of 822 Bus interface Internal data bus 16.1.3 Pin Configuration Table 16.1 summarizes the D/A converter's input and output pins. Table 16.1 D/A Converter Pins Pin Name Analog power supply pin Analog ground pin Analog output pin 0 Analog output pin 1 Reference voltage input pin Abbreviation AVCC AVSS DA0 DA1 VREF I/O Input Input Output Output Input Function Analog power supply Analog ground and reference voltage Analog output, channel 0 Analog output, channel 1 Analog reference voltage 16.1.4 Register Configuration Table 16.2 summarizes the D/A converter's registers. Table 16.2 D/A Converter Registers Address* H'FFDC H'FFDD H'FFDE H'FF5C Name D/A data register 0 D/A data register 1 D/A control register D/A standby control register Abbreviation DADR0 DADR1 DACR DASTCR R/W R/W R/W R/W R/W Initial Value H'00 H'00 H'1F H'FE Note: * Lower 16 bits of the address Rev. 2.0, 03/01, page 549 of 822 16.2 16.2.1 Bit Register Descriptions D/A Data Registers 0 and 1 (DADR0/1) 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W Initial value Read/Write The D/A data registers (DADR0 and DADR1) are 8-bit readable/writable registers that store the data to be converted. When analog output is enabled, the D/A data register values are constantly converted and output at the analog output pins. The D/A data registers are initialized to H'00 by a reset and in standby mode. 16.2.2 Bit Initial value Read/Write D/A Control Register (DACR) 7 DAOE1 0 R/W 6 DAOE0 0 R/W 5 DAE 0 R/W 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- D/A enable Controls D/A conversion D/A output enable 0 Controls D/A conversion and analog output D/A output enable 1 Controls D/A conversion and analog output DACR is an 8-bit readable/writable register that controls the operation of the D/A converter. DACR is initialized to H'1F by a reset and in standby mode. Bit 7--D/A Output Enable 1 (DAOE1): Controls D/A conversion and analog output. Bit 7: DAOE1 0 1 Description DA1 analog output is disabled Channel-1 D/A conversion and DA1 analog output are enabled (Initial value) Rev. 2.0, 03/01, page 550 of 822 Bit 6--D/A Output Enable 0 (DAOE0): Controls D/A conversion and analog output. Bit 6: DAOE0 0 1 Description DA0 analog output is disabled Channel-0 D/A conversion and DA0 analog output are enabled (Initial value) Bit 5--D/A Enable (DAE): Controls D/A conversion, together with bits DAOE0 and DAOE1. When the DAE bit is cleared to 0, analog conversion is controlled independently in channels 0 and 1. When the DAE bit is set to 1, analog conversion is controlled together in channels 0 and 1. Output of the conversion results is always controlled independently by DAOE0 and DAOE1. Bit 7: DAOE1 0 Bit 6: DAOE0 0 1 Bit 5: DAE -- 0 1 1 0 0 1 1 -- Description D/A conversion is disabled in channels 0 and 1 D/A conversion is enabled in channel 0 D/A conversion is disabled in channel 1 D/A conversion is enabled in channels 0 and 1 D/A conversion is disabled in channel 0 D/A conversion is enabled in channel 1 D/A conversion is enabled in channels 0 and 1 D/A conversion is enabled in channels 0 and 1 When the DAE bit is set to 1, even if bits DAOE0 and DAOE1 in DACR and the ADST bit in ADCSR are cleared to 0, the same current is drawn from the analog power supply as during A/D and D/A conversion. Bits 4 to 0--Reserved: Read-only bits, always read as 1. Rev. 2.0, 03/01, page 551 of 822 16.2.3 D/A Standby Control Register (DASTCR) DASTCR is an 8-bit readable/writable register that enables or disables D/A output in software standby mode. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- Reserved bits D/A standby enable Enables or disables D/A output in software standby mode 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 DASTE 0 R/W DASTCR is initialized to H'FE by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 1--Reserved: Read-only bits, always read as 1. Bit 0--D/A Standby Enable (DASTE): Enables or disables D/A output in software standby mode. Bit 0: DASTE 0 1 Description D/A output is disabled in software standby mode D/A output is enabled in software standby mode (Initial value) Rev. 2.0, 03/01, page 552 of 822 16.3 Operation The D/A converter has two built-in D/A conversion circuits that can perform conversion independently. D/A conversion is performed constantly while enabled in DACR. If the DADR0 or DADR1 value is modified, conversion of the new data begins immediately. The conversion results are output when bits DAOE0 and DAOE1 are set to 1. An example of D/A conversion on channel 0 is given next. Timing is indicated in figure 16.2. 1. Data to be converted is written in DADR0. 2. Bit DAOE0 is set to 1 in DACR. D/A conversion starts and DA0 becomes an output pin. The converted result is output after the conversion time. The output value is (DADR0 contents/256) x VREF. Output of this conversion result continues until the value in DADR0 is modified or the DAOE0 bit is cleared to 0. 3. If the DADR0 value is modified, conversion starts immediately, and the result is output after the conversion time. 4. When the DAOE0 bit is cleared to 0, DA0 becomes an input pin. DADR0 write cycle DACR write cycle DADR0 write cycle DACR write cycle Address bus DADR0 DAOE0 DA 0 High-impedance state t DCONV Legend t DCONV : D/A conversion time Conversion result 2 Conversion data 1 Conversion data 2 Conversion result 1 t DCONV Figure 16.2 Example of D/A Converter Operation Rev. 2.0, 03/01, page 553 of 822 16.4 D/A Output Control In the H8/3052F, D/A converter output can be enabled or disabled in software standby mode. When the DASTE bit is set to 1 in DASTCR, D/A converter output is enabled in software standby mode. The D/A converter registers retain the values they held prior to the transition to software standby mode. When D/A output is enabled in software standby mode, the reference supply current is the same as during normal operation. Rev. 2.0, 03/01, page 554 of 822 Section 17 RAM 17.1 Overview The H8/3052F has 8 kbytes of high-speed static RAM on-chip. The RAM is connected to the CPU by a 16-bit data bus. The CPU accesses both byte data and word data in two states, making the RAM useful for rapid data transfer. The on-chip RAM of the H8/3052F is assigned to addresses H'FDF10 to H'FFF0F in modes 1, 2, 5, and 7, and to addresses H'FFDF10 to H'FFFF0F in modes 3, 4, and 6. The RAM enable bit (RAME) in the system control register (SYSCR) can enable or disable the on-chip RAM. 17.1.1 Block Diagram Figure 17.1 shows a block diagram of the on-chip RAM. Internal data bus (upper 8 bits) Internal data bus (lower 8 bits) Bus interface SYSCR H'FDF10* H'FDF12* H'FDF11* H'FDF13* On-chip RAM H'FFF0E* Even addresses Legend SYSCR: System control register H'FFF0F* Odd addresses Note: * This example is of the H8/3052F operating in mode 7. The lower 20 bits of the address are shown. Figure 17.1 RAM Block Diagram Rev. 2.0, 03/01, page 555 of 822 17.1.2 Register Configuration The on-chip RAM is controlled by SYSCR. Table 17.1 gives the address and initial value of SYSCR. Table 17.1 System Control Register Address* H'FFF2 Name System control register Abbreviation SYSCR R/W R/W Initial Value H'0B Note: * Lower 16 bits of the address. 17.2 Bit System Control Register (SYSCR) 7 SSBY 0 R/W 6 STS2 0 R/W 5 STS1 0 R/W 4 STS0 0 R/W 3 UE 1 R/W 2 NMIEG 0 R/W 1 -- 1 -- 0 RAME 1 R/W Initial value Read/Write RAM enable Enables or disables on-chip RAM Reserved bit NMI edge select User bit enable Standby timer select 2 to 0 Software standby One function of SYSCR is to enable or disable access to the on-chip RAM. The on-chip RAM is enabled or disabled by the RAME bit in SYSCR. For details about the other bits, see section 3.3, System Control Register (SYSCR). Bit 0--RAM Enable (RAME): Enables or disables the on-chip RAM. The RAME bit is initialized at the rising edge of the input at the 5(6 pin. It is not initialized in software standby mode. Bit 0: RAME 0 1 Description On-chip RAM is disabled On-chip RAM is enabled (Initial value) Rev. 2.0, 03/01, page 556 of 822 17.3 Operation When the RAME bit is set to 1, the on-chip RAM is enabled. Accesses to addresses H'FDF10 to H'FFF0F in the H8/3052F in modes 1, 2, 5, and 7, addresses H'FFDF10 to H'FFFF0F in the H8/3052F in modes 3, 4, and 6 are directed to the on-chip RAM. In modes 1 to 6 (expanded modes), when the RAME bit is cleared to 0, the external address space is accessed. In mode 7 (single-chip mode), when the RAME bit is cleared to 0, the on-chip RAM is not accessed: read access always results in H'FF data, and write access is ignored. Since the on-chip RAM is connected to the CPU by an internal 16-bit data bus, it can be written and read by word access. It can also be written and read by byte access. Byte data is accessed in two states using the upper 8 bits of the data bus. Word data starting at an even address is accessed in two states using all 16 bits of the data bus. Rev. 2.0, 03/01, page 557 of 822 Rev. 2.0, 03/01, page 558 of 822 Section 18 ROM 18.1 Features The H8/3052F has 512 kbytes of on-chip flash memory. The features of the flash memory are summarized below. * Four flash memory operating modes Program mode Erase mode Program-verify mode Erase-verify mode * Programming/erase methods The flash memory is programmed 128 bytes at a time. Block erase (in single-block units) can be performed. To erase the entire flash memory, each block must be erased in turn. Block erasing can be performed as required on 4 kbytes, 32 kbytes, and 64 kbytes blocks. * Programming/erase times The flash memory programming time is 10 ms (typ.) for simultaneous 128-byte programming, equivalent approximately to 80 s (typ.) per byte, and the erase time is 100 ms (typ.). * Reprogramming capability The flash memory can be reprogrammed up to 100 times. * On-board programming modes There are two modes in which flash memory can be programmed/erased/verified on-board: Boot mode User program mode * Automatic bit rate adjustment With data transfer in boot mode, the LSI's bit rate can be automatically adjusted to match the transfer bit rate of the host. * Flash memory emulation in RAM Flash memory programming can be emulated in real time by overlapping a part of RAM onto flash memory. * Protect modes There are two protect modes, hardware and software, which allow protected status to be designated for flash memory program/erase/verify operations. * PROM mode Flash memory can be programmed/erased in PROM mode, using a PROM programmer, as well as in on-board programming mode. Rev. 2.0, 03/01, page 559 of 822 18.2 18.2.1 Overview Block Diagram Internal address bus Internal data bus (16 bits) Module bus FLMCR1 FLMCR2 EBR1 EBR2 RAMCR Bus interface/controller Operating mode FWE pin Mode pin Flash memory (512 kbytes) Legend FLMCR1: FLMCR2: EBR1: EBR2: RAMCR: Flash memory control register 1 Flash memory control register 2 Erase block register 1 Erase block register 2 RAM control register Figure 18.1 Block Diagram of Flash Memory 18.2.2 Mode Transitions When the mode pins and the FWE pin are set in the reset state and a reset-start is executed, the microcomputer enters an operating mode as shown in figure 18.2. In user mode, flash memory can be read but not programmed or erased. The boot, user program and PROM modes are provided as modes to write and erase the flash memory. Rev. 2.0, 03/01, page 560 of 822 *1, *3 RES = 0 User mode *3 FWE = 1 FWE = 0 Reset state RES = 0 RES = 0 *3 RES = 0 PROM mode *2 User program mode *1 Boot mode On-board programming mode Notes: Only make a transition between user mode and user program mode when the CPU is not accessing the flash memory. 1. RAM emulation possible 2. The H8/3052F is placed in PROM mode by means of a dedicated PROM writer. 3. Mode settings are shown in the following table. Mode FWE Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Boot mode 5 Boot mode 6 Boot mode 7 Setting prohibited User program mode 5 User program mode 6 User program mode 7 0 0 0 0 1 1 1 1 0 0 0 1 1 1 1 Pins MD2 MD1 0 1 1 0 0 1 1 0 1 1 0 0 1 1 MD0 1 0 1 0 1 0 1 1 0 1 0 1 0 1 1 Figure 18.2 Flash Memory State Transitions Rev. 2.0, 03/01, page 561 of 822 State transitions between the normal user mode and on-board programming mode are performed by changing the FWE pin level from high to low or from low to high. To prevent misoperation (erroneous programming or erasing) in these cases, the bits in the flash memory control registers (FLMCR1, FLMCR2) should be cleared to 0 before making such a transition. After the bits are cleared, a wait time is necessary. Normal operation is not guaranteed if this wait time is insufficient. Rev. 2.0, 03/01, page 562 of 822 18.2.3 On-Board Programming Modes Boot Mode 1. Initial state The old program version or data remains written in the flash memory. The user should prepare the programming control program and new application program beforehand in the host. 2. Programming control program transfer When boot mode is entered, the boot program in the H8/3052F (originally incorporated in the chip) is started and the programming control program in the host is transferred to RAM via SCI communication. The boot program required for flash memory erasing is automatically transferred to the RAM boot program area. Host  " ! , Programming control program New application program New application program Host H8/3052F H8/3052F Boot program SCI Boot program SCI Flash memory RAM Flash memory RAM Boot program area Programming control program Application program (old version) Application program (old version) 3. Flash memory initialization The erase program in the boot program area (in RAM) is executed, and the flash memory is initialized (to H'FF). In boot mode, total flash memory erasure is performed, without regard to blocks. Host 4. Writing new application program The programming control program transferred from the host to RAM is executed, and the new application program in the host is written into the flash memory. Host New application program H8/3052F H8/3052F Boot program SCI Boot program SCI Flash memory RAM Flash memory RAM Boot program area Programming control program Boot program area Programming control program Flash memory preprogramming erase New application program Program execution state Rev. 2.0, 03/01, page 563 of 822 User Program Mode 1. Initial state The FWE assessment program that confirms that user program mode has been entered, and the program that will transfer the programming/erase control program from flash memory to on-chip RAM should be written into the flash memory by the user beforehand. The programming/erase control program should be prepared in the host or in the flash memory. Host Programming/ erase control program New application program 2. Programming/erase control program transfer When user program mode is entered, user software confirms this fact, executes transfer program in the flash memory, and transfers the programming/erase control program to RAM. , Host New application program H8/3052F H8/3052F Boot program SCI Boot program SCI Flash memory RAM Flash memory RAM FWE assessment program FWE assessment program Transfer program Transfer program Programming/ erase control program Application program (old version) Application program (old version) 3. Flash memory initialization The programming/erase program in RAM is executed, and the flash memory is initialized (to H'FF). Erasing can be performed in block units, but not in byte units. Host 4. Writing new application program Next, the new application program in the host is written into the erased flash memory blocks. Do not write to unerased blocks. Host New application program H8/3052F H8/3052F Boot program SCI Boot program SCI Flash memory RAM Flash memory RAM FWE assessment program Transfer program FWE assessment program Transfer program Programming/ erase control program Programming/ erase control program Flash memory erase New application program Program execution state Rev. 2.0, 03/01, page 564 of 822 18.2.4 Flash Memory Emulation in RAM In the H8/3052F, flash memory programming can be emulated in real time by overlapping the flash memory with part of RAM ("overlap RAM"). When the emulation block set in RAMCR is accessed while the emulation function is being executed, data written in the overlap RAM is read. Emulation should be performed in user mode or user program mode. SCI Flash memory Emulation block RAM Overlap RAM (emulation is performed on data written in RAM) Application program Execution state Figure 18.3 Reading Overlap RAM Data in User Mode or User Program Mode When overlap RAM data is confirmed, clear the RAMS bit to release RAM overlap, and actually perform writes to the flash memory. When the programming control program is transferred to RAM in on-board programming mode, ensure that the transfer destination and the overlap RAM do not overlap, as this will cause data in the overlap RAM to be rewritten. Rev. 2.0, 03/01, page 565 of 822 SCI Flash memory Programming data RAM Application program Overlap RAM (programming data) Programming control program execution state Figure 18.4 Writing Overlap RAM Data in User Program Mode 18.2.5 Item Total erase Block erase Programming control program* Differences between Boot Mode and User Program Mode Boot Mode Yes No Boot program is initiated, and programming control program is transferred from host to on-chip RAM, and executed there. User Program Mode Yes Yes Program that controls programming program in flash memory is executed. Program should be written beforehand in PROM mode and boot mode. Note: * To be provided by the user, in accordance with the recommended algorithm. Rev. 2.0, 03/01, page 566 of 822 18.2.6 Block Configuration The flash memory in the H8/3052F is divided into seven 64-kbyte blocks, one 32-kbyte block, and eight 4-kbyte blocks. Address H'7FFFF 64 kbytes 64 kbytes 64 kbytes 64 kbytes 512 kbytes 64 kbytes 64 kbytes 64 kbytes 32 kbytes 4 kbytes x 8 Address H'00000 Figure 18.5 Erase Area Block Divisions Rev. 2.0, 03/01, page 567 of 822 18.3 Pin Configuration The flash memory is controlled by means of the pins shown in table 18.1. Table 18.1 Pin Configuration Pin Name Reset Flash write enable Mode 2 Mode 1 Mode 0 Transmit data Receive data Abbreviation 5(6 FWE MD2 MD1 MD0 TxD1 RxD1 I/O Input Input Input Input Input Output Input Function Reset Flash program/erase protection by hardware Sets LSI operating mode Sets LSI operating mode Sets LSI operating mode Serial transmit data output Serial receive data input 18.4 Register Configuration 1 The registers * used to control the on-chip flash memory when enabled are shown in table 18.2. Table 18.2 Register Configuration Register Name Flash memory control register 1 Flash memory control register 2 Erase block register 1 Erase block register 2 RAM control register Abbreviation FLMCR1* FLMCR2* 6 EBR1* 6 EBR2* 6 RAMCR* 6 6 R/W R/W* R/W* R/W* R/W 3 3 3 Initial Value H'00* H'00 5 H'00* 5 H'00* 4 Address* H'FF40 H'FF41 H'FF42 H'FF43 H'FF47 2 3 R/W* H'F0 Notes: 1. Access is prohibited to lower 16 address bits H'FF44 to H'FF46 and H'FF48 to H'FF4F. 2. Lower 16 bits of the address. 3. If the chip is in a mode in which the on-chip flash memory is disabled, a read will return H'00 and writes are invalid. Writes are also invalid when the FWE bit in FLMCR1 is not set to 1. 4. When a high level is input to the FWE pin, the initial value is H'80. 5. When a low level is input to the FWE pin, or if a high level is input and the SWE1 bit in FLMCR1 or SWE2 bit in FLMCR2 is not set, these registers are initialized to H'00. 6. FLMCR1, FLMCR2, EBR1, and EBR2, and RAMCR are 8-bit registers. Byte access must be used on these registers (do not use word or longword access). Rev. 2.0, 03/01, page 568 of 822 18.5 18.5.1 Register Descriptions Flash Memory Control Register 1 (FLMCR1) FLMCR1 is an 8-bit register used for flash memory operating mode control. Program-verify mode or erase-verify mode for addresses H'00000 to H'3FFFF is entered by setting SWE1 bit to 1 when FWE = 1, then setting the PV1 or EV1 bit. Program mode for addresses H'00000 to H'3FFFF is entered by setting SWE1 bit to 1 when FWE = 1, then setting the PSU1 bit, and finally setting the P1 bit. Erase mode for addresses H'00000 to H'3FFFF is entered by setting SWE1 bit to 1 when FWE = 1, then setting the ESU1 bit, and finally setting the E1 bit. FLMCR1 is initialized by a power-on reset, and in hardware standby mode and software standby mode. Its initial value is H'80 when a high level is input to the FWE pin, and H'00 when a low level is input. When on-chip flash memory is disabled, a read will return H'00, and writes are invalid. Writes are enabled only in the following cases: Writes to bit SWE1 of FLMCR1 enabled when FWE = 1, to bits ESU1, PSU1, EV1, and PV1 when FWE = 1 and SWE1 = 1, to bit E1 when FWE = 1, SWE1 = 1 and ESU1 = 1, and to bit P1 when FWE = 1, SWE1 = 1, and PSU1 = 1. Bit Initial value Read/Write 7 FWE 1/0 R 6 SWE1 0 R/W 5 ESU1 0 R/W 4 PSU1 0 R/W 3 EV1 0 R/W 2 PV1 0 R/W 1 E1 0 R/W 0 P1 0 R/W Bit 7--Flash Write Enable Bit (FWE): Sets hardware protection against flash memory programming/erasing. Bit 7: FWE 0 1 Description When a low level is input to the FWE pin (hardware-protected state) When a high level is input to the FWE pin Bit 6--Software Write Enable Bit 1 (SWE1): Enables or disables flash memory programming and erasing (applicable addresses: H'00000 to H'3FFFF). Set this bit when setting bits 5 to 0, bits 7 to 0 of EBR1, and bits 3 to 0 of EBR2. Bit 6: SWE1 0 1 Description Writes disabled Writes enabled* [Setting condition] When FWE = 1 Note: * Do not execute a SLEEP instruction while the SWE1 bit is set to 1. (Initial value) Rev. 2.0, 03/01, page 569 of 822 Bit 5--Erase Setup Bit 1 (ESU1): Prepares for a transition to erase mode (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, PSU1, EV1, PV1, E1, or P1 bit at the same time. Set this bit to 1 before setting bit E1 to 1 in FLMCR1. Bit 5: ESU1 0 1 Description Erase setup cleared Erase setup [Setting condition] When FWE = 1 and SWE1 = 1 (Initial value) Bit 4--Program Setup Bit 1 (PSU1): Prepares for a transition to program mode (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, ESU1, EV1, PV1, E1, or P1 bit at the same time. Set this bit to 1 before setting bit P1 to 1 in FLMCR1. Bit 4: PSU1 0 1 Description Program setup cleared Program setup [Setting condition] When FWE = 1 and SWE1 = 1 (Initial value) Bit 3--Erase-Verify 1 (EV1): Selects erase-verify mode transition or clearing (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, ESU1, PSU1, PV1, E1, or P1 bit at the same time. Bit 3: EV1 0 1 Description Erase-verify mode cleared Transition to erase-verify mode [Setting condition] When FWE = 1 and SWE1 = 1 (Initial value) Bit 2--Program-Verify 1 (PV1): Selects program-verify mode transition or clearing (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, ESU1, PSU1, EV1, E1, or P1 bit at the same time. Bit 2: PV1 0 1 Description Program-verify mode cleared Transition to program-verify mode [Setting condition] When FWE = 1 and SWE1 = 1 (Initial value) Rev. 2.0, 03/01, page 570 of 822 Bit 1--Erase 1 (E1): Selects erase mode transition or clearing (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, ESU1, PSU1, EV1, PV1, or P1 bit at the same time. Bit 1: E1 0 1 Description Erase mode cleared Transition to erase mode* [Setting condition] When FWE = 1, SWE1 = 1, and ESU1 = 1 Note: * Do not access flash memory while the E1 bit is set to 1. (Initial value) Bit 0--Program (P1): Selects program mode transition or clearing (applicable addresses: H'00000 to H'3FFFF). Do not set the SWE1, PSU1, ESU1, EV1, PV1, or E1 bit at the same time. Bit 0: P1 0 1 Description Program mode cleared Transition to program mode* [Setting condition] When FWE = 1, SWE1 = 1, and PSU1 = 1 Note: * Do not access flash memory while the P1 bit is set. (Initial value) 18.5.2 Flash Memory Control Register 2 (FLMCR2) FLMCR2 is an 8-bit register used for flash memory operating mode control. Program-verify mode or erase-verify mode for addresses H'40000 to H'7FFFF is entered by setting SWE2 to 1 when FWE (FLMCR1) = 1, then setting the EV2 or PV2 bit. Program mode for addresses H'40000 to H'7FFFF is entered by setting SWE2 to 1 when FWE (FLMCR1) = 1, then setting the PSU2 bit, and finally setting the P2 bit. Erase mode for addresses H'40000 to H'7FFFF is entered by setting SWE2 to 1 when FWE (FLMCR1) = 1, then setting the ESU2 bit, and finally setting the E2 bit. FLMCR2 is initialized to H'00 by a power-on reset, in hardware standby mode and software standby mode, when a low level is input to the FWE pin, and when a high level is input to the FWE pin and the SWE2 bit in FLMCR2 is not set (the exception is the FLER bit, which is initialized only by a power-on reset and in hardware standby mode). When on-chip flash memory is disabled, a read will return H'00, and writes are invalid. Writes are enabled only in the following cases: Writes to bit SWE2 of FLMCR2 enabled when FWE (FLMCR1) = 1, to bits ESU2, PSU2, EV2, and PV2 when FEW (FLMCR1) = 1 and SWE2 = 1, to bit E2 when FWE (FLMCR1) = 1, SWE2 = 1, and ESU2 = 1, to bit P2 when FWE (FLMCR1) = 1, SWE2 = 1, and PSU2 = 1. Rev. 2.0, 03/01, page 571 of 822 Bit Initial value Read/Write 7 FLER 0 R 6 SWE2 0 R/W 5 ESU2 0 R/W 4 PSU2 0 R/W 3 EV2 0 R/W 2 PV2 0 R/W 1 E2 0 R/W 0 P2 0 R/W Bit 7--Flash Memory Error (FLER): Indicates that an error has occurred during an operation on flash memory (programming or erasing). When FLER is set to 1, flash memory goes to the error-protection state. Bit 7: FLER 0 Description Flash memory is operating normally [Clearing condition] Power-on reset or hardware standby mode 1 An error has occurred during flash memory programming/erasing Flash memory program/erase protection (error protection) is enabled [Setting condition] See 18.8.3 Error Protection (Initial value) Flash memory program/erase protection (error protection) is disabled Bit 6--Software Write Enable Bit 2 (SWE2): Enables or disables flash memory programming and erasing (applicable addresses: H'40000 to H'7FFFF). Set this bit when setting bits 5 to 0 and bits 7 to 4 of EBR2. Bit 6: SWE2 0 1 Description Writes disabled Writes enabled* [Setting condition] When FWE = 1 Note: * Do not execute a SLEEP instruction while the SWE2 bit is set to 1. (Initial value) Bit 5--Erase Setup Bit 2 (ESU2): Prepares for a transition to erase mode (applicable addresses: H'40000 to H'7FFFF). Set this bit to 1 before setting bit E2 to 1 in FLMCR2. Do not set the PSU2, EV2, PV2, E2, or P2 bit at the same time. Bit 5: ESU2 0 1 Description Erase setup cleared Erase setup [Setting condition] When FWE = 1 and SWE2 = 1 (Initial value) Rev. 2.0, 03/01, page 572 of 822 Bit 4--Program Setup Bit 2 (PSU2): Prepares for a transition to program mode (applicable addresses: H'40000 to H'7FFFF). Set this bit to 1 before setting bit P2 to 1 in FLMCR2. Do not set the ESU2, EV2, PV2, E2, or P2 bit at the same time. Bit 4: PSU2 0 1 Description Program setup cleared Program setup [Setting condition] When FWE = 1 and SWE2 = 1 (Initial value) Bit 3--Erase-Verify 2 (EV2): Selects erase-verify mode transition or clearing (applicable addresses: H'40000 to H'7FFFF). Do not set the ESU2, PSU2, PV2, E2, or P2 bit at the same time. Bit 3: EV2 0 1 Description Erase-verify mode cleared Transition to erase-verify mode [Setting condition] When FWE = 1 and SWE2 = 1 (Initial value) Bit 2--Program-Verify 2 (PV2): Selects program-verify mode transition or clearing (applicable addresses: H'40000 to H'7FFFF). Do not set the ESU2, PSU2, EV2, E2, or P2 bit at the same time. Bit 2: PV2 0 1 Description Program-verify mode cleared Transition to program-verify mode [Setting condition] When FWE = 1 and SWE2 = 1 (Initial value) Bit 1--Erase 2 (E2): Selects erase mode transition or clearing (applicable addresses: H'40000 to H'7FFFF). Do not set the ESU2, PSU2, EV2, PV2, or P2 bit at the same time. Bit 1: E2 0 1 Description Erase mode cleared Transition to erase mode* [Setting condition] When FWE = 1, SWE2 = 1, and ESU2 = 1 (Initial value) Note: * Do not access flash memory while the E2 bit is set to 1. Rev. 2.0, 03/01, page 573 of 822 Bit 0--Program 2 (P2): Selects program mode transition or clearing (applicable addresses: H'40000 to H'7FFFF). Do not set the ESU2, PSU2, EV2, PV2, or E2 bit at the same time. Bit 0: P2 0 1 Description Program mode cleared Transition to program mode* [Setting condition] When FWE = 1, SWE2 = 1, and PSU2 = 1 (Initial value) Note: * Do not access flash memory while the P2 bit is set. 18.5.3 Erase Block Register 1 (EBR1) EBR1 is an 8-bit register that specifies the flash memory erase area block by block. EBR1 is initialized to H'00 by a power-on reset, in hardware standby mode and software standby mode, when a low level is input to the FWE pin, and when a high level is input to the FWE pin and the SWE1 bit in FLMCR1 is not set. When a bit in EBR1 is set to 1, the corresponding block can be erased. Other blocks are erase-protected. Only one of the bits of EBR1 and EBR2 combined can be set. Do not set more than one bit, as this will cause all the bits in both EBR1 and EBR2 to be automatically cleared to 0. When on-chip flash memory is disabled, a read will return H'00, and writes are invalid. The flash memory block configuration is shown in table 18.3. Bit Initial value Read/Write 7 EB7 0 R/W 6 EB6 0 R/W 5 EB5 0 R/W 4 EB4 0 R/W 3 EB3 0 R/W 2 EB2 0 R/W 1 EB1 0 R/W 0 EB0 0 R/W Rev. 2.0, 03/01, page 574 of 822 18.5.4 Erase Block Register 2 (EBR2) EBR2 is an 8-bit register that specifies the flash memory erase area block by block. EBR2 is initialized to H'00 by a power-on reset, in hardware standby mode and software standby mode, when a low level is input to the FWE pin. Bits EB11 to EB8 will be initialized to 0 if bit SWE1 of FLMCR1 is not set, even though a high level is input to pin FWE. Also, bits EB15 to EB12 will be initialized to 0 if bit SWE2 of FLMCR2 is not set. When a bit in EBR2 is set to 1, the corresponding block can be erased. Other blocks are erase-protected. Only one of the bits of EBR1 and EBR2 combined can be set. Do not set more than one bit, as this will cause all the bits in both EBR1 and EBR2 to be automatically cleared to 0. When on-chip flash memory is disabled, a read will return H'00, and writes are invalid. The flash memory block configuration is shown in table 18.3. Bit Initial value Read/Write 7 EB15 0 R/W 6 EB14 0 R/W 5 EB13 0 R/W 4 EB12 0 R/W 3 EB11 0 R/W 2 EB10 0 R/W 1 EB9 0 R/W 0 EB8 0 R/W Table 18.3 Flash Memory Erase Blocks Block (Size) EB0 (4 kbytes) EB1 (4 kbytes) EB2 (4 kbytes) EB3 (4 kbytes) EB4 (4 kbytes) EB5 (4 kbytes) EB6 (4 kbytes) EB7 (4 kbytes) EB8 (32 kbytes) EB9 (64 kbytes) EB10 (64 kbytes) EB11 (64 kbytes) EB12 (64 kbytes) EB13 (64 kbytes) EB14 (64 kbytes) EB15 (64 kbytes) Addresses H'000000-H'000FFF H'001000-H'001FFF H'002000-H'002FFF H'003000-H'003FFF H'004000-H'004FFF H'005000-H'005FFF H'006000-H'006FFF H'007000-H'007FFF H'008000-H'00FFFF H'010000-H'01FFFF H'020000-H'02FFFF H'030000-H'03FFFF H'040000-H'04FFFF H'050000-H'05FFFF H'060000-H'06FFFF H'070000-H'07FFFF Rev. 2.0, 03/01, page 575 of 822 18.5.5 RAM Control Register (RAMCR) RAMCR specifies the area of flash memory to be overlapped with part of RAM when emulating real-time flash memory programming. RAMCR initialized to H'F0 by a power-on reset and in hardware standby mode. It is not initialized by a manual reset and in software standby mode. RAMCR settings should be made in user mode or user program mode. Flash memory area divisions are shown in table 18.4. To ensure correct operation of the emulation function, the ROM for which RAM emulation is performed should not be accessed immediately after this register has been modified. Normal execution of an access immediately after register modification is not guaranteed. Bit Initial value Read/Write 7 -- 1 6 -- 1 5 -- 1 4 -- 1 3 RAMS 0 R/W 2 RAM2 0 R/W 1 RAM1 0 R/W 0 RAM0 0 R/W Bits 7 to 4--Reserved: These bits always read 1. Bit 3--RAM Select (RAMS): Specifies selection or non-selection of flash memory emulation in RAM. When RAMS = 1, all flash memory block are program/erase-protected. Bit 3: RAMS 0 1 Description Emulation not selected Program/erase-protection of all flash memory blocks is disabled Emulation selected Program/erase-protection of all flash memory blocks is enabled (Initial value) Bits 2 to 0--Flash Memory Area Selection: These bits are used together with bit 3 to select the flash memory area to be overlapped with RAM. (See table 18.4.) Rev. 2.0, 03/01, page 576 of 822 Table 18.4 Flash Memory Area Divisions Addresses H'FFE000-H'FFEFFF H'000000-H'000FFF H'001000-H'001FFF H'002000-H'002FFF H'003000-H'003FFF H'004000-H'004FFF H'005000-H'005FFF H'006000-H'006FFF H'007000-H'007FFF *: Don't care Block Name RAM area 4 kbytes EB0 (4 kbytes) EB1 (4 kbytes) EB2 (4 kbytes) EB3 (4 kbytes) EB4 (4 kbytes) EB5 (4 kbytes) EB6 (4 kbytes) EB7 (4 kbytes) RAMS 0 1 1 1 1 1 1 1 1 RAM1 * 0 0 0 0 1 1 1 1 RAM1 * 0 0 1 1 0 0 1 1 RAM0 * 0 1 0 1 0 1 0 1 18.6 On-Board Programming Modes When pins are set to on-board programming mode and a reset-start is executed, a transition is made to the on-board programming state in which program/erase/verify operations can be performed on the on-chip flash memory. There are two on-board programming modes: boot mode and user program mode. The pin settings for transition to each of these modes are shown in table 18.5. For a diagram of the transitions to the various flash memory modes, see figure 18.2. Table 18.5 Setting On-Board Programming Modes Mode Boot mode Mode 5 Mode 6 Mode 7 User program mode Mode 5 Mode 6 Mode 7 FWE 1* MD2 0* 0* 0* 1* 1* 1* MD1 0 1 1 0 1 1 MD0 1 0 1 1 0 1 Notes 0: VIL 1: VIH Notes: 1. For the high-level application timing, see items 6 and 7 in Notes on Use of Boot Mode. 2. In boot mode, the inverse of the MD2 setting should be input. 3. In boot mode, the mode control register (MDCR) can be used to monitor the status of modes 5, 6, and 7, in the same way as in normal mode. Rev. 2.0, 03/01, page 577 of 822 18.6.1 Boot Mode When boot mode is used, the flash memory programming control program must be prepared in the host beforehand. The SCI channel to be used is set to asynchronous mode. When a reset-start is executed after the LSI's pins have been set to boot mode, the boot program built into the LSI is started and the programming control program prepared in the host is serially transmitted to the LSI via the SCI. In the LSI, the programming control program received via the SCI is written into the programming control program area in on-chip RAM. After the transfer is completed, control branches to the start address of the programming control program area and the programming control program execution state is entered (flash memory programming is performed). The transferred programming control program must therefore include coding that follows the programming algorithm given later. The system configuration in boot mode is shown in figure 18.6, and the boot mode execution procedure in figure 18.7. LSI Flash memory Host Write data reception Verify data transmission RXD1 SCI1 TXD1 On-chip RAM Figure 18.6 System Configuration in Boot Mode Rev. 2.0, 03/01, page 578 of 822 Start Set pins to boot program mode and execute reset-start Host transfers data (H'00) continuously at prescribed bit rate This LSI measures low period of H'00 data transmitted by host 1. Set this LSI to the boot mode and reset starts the LSI. 2. Set the host to the prescribed bit rate (4800, 9600, 19200) and consecutively send H'00 data in 8-bit data, 1 stop bit format. 3. This LSI repeatedly measures the RXD1 pin Low period and calculates the asynchronous communication bit rate at which the host performs transfer. 4. At the end of SCI bit rate adjustment, this LSI sends one byte of H'00 data to signal the end of adjustment. 5. Check if the host normally received the one byte bit rate adjustment end signal sent from this LSI and sent one byte of H'55 data. 6. After H'55 is sent, the host receives H'AA and sends the byte count of the user program that is transferred to this LSI. Send the 2-byte count in upper byte and lower byte order. Then sequentially send the program set by the user. This LSI sequentially sends (echo back) each byte of the received byte count and user program to the host as verification data. 7. This LSI sequentially writes the received user program to the on-chip RAM area (H'FFE710 to HFFFF0F). 8. Before executing the transferred user program, this LSI checks if data was written to flash memory after control branched to the RAM boot program area (H'FFDF10). If data was already written to flash memory, all the blocks are erased. 9. After sending H'AA, this LSI branches to the on-chip RAM area (H'FFE710) and executes the user program written to that area. 1 2 3 This LSI calculates bit rate and sets value in bit rate register After bit rate adjustment, this LSI transmits one byte of H'00 data to host to indicate end of adjustment Host confirms normal reception of bit rate adjustment end indication (H'00), and transmits one byte of H'55 data After receiving H'55, this LSI sends H'AA and receives two bytes of the byte count (N) of the program transferred to the on-chip RAM*1 4 5 6 This LSI transfers the user program to RAM*2 7 This LSI calculates the remaining number of bytes to be sent (N = N - 1) Transfer end byte count N = 0? Yes After branching to the RAM boot program area (H'FFDF10 to HFFE70F), this LSI checks the data in the flashmemory user area. No Notes: 1. The RAM area that can be used by the user is 6 kbyte. Set the transfer byte count to within 6 kbyte. Always send the 2-byte transfer byte count in upper byte and lower byte order. Transfer byte count example: For 256 bytes (H'0100), upper byte H'01, lower byte H'00. 2. Set the part that controls the user program flash memory at the program according to the flash memory programming/erase algorithms described later. 3. When a memory cell malfunctions and cannot be erased, this LSI sends one H'FF byte as an erase error and stops the erase operation and subsequent operations. 8 All data = H'FF? Yes No Erase all blocks of flash memory*3 9 After sending H'AA, this LSI branches to the RAM area (H'FFE710) and executes the user program transferred to the RAM Figure 18.7 Boot Mode Execution Procedure Rev. 2.0, 03/01, page 579 of 822 Automatic SCI Bit Rate Adjustment Start bit Stop bit D0 D1 D2 D3 D4 D5 D6 D7 Low period (9 bits) measured (H'00 data) High period (1 or more bits) When boot mode is initiated, the LSI measures the low period of the asynchronous SCI communication data (H'00) transmitted continuously from the host. The SCI transmit/receive format should be set as follows: 8-bit data, 1 stop bit, no parity. The LSI calculates the bit rate of the transmission from the host from the measured low period, and transmits one H'00 byte to the host to indicate the end of bit rate adjustment. The host should confirm that this adjustment end indication (H'00) has been received normally, and transmit one H'55 byte to the LSI. If reception cannot be performed normally, initiate boot mode again (reset), and repeat the above operations. Depending on the host's transmission bit rate and the LSI's system clock frequency, there will be a discrepancy between the bit rates of the host and the LSI. Set the host transfer bit rate at 4,800, 9,600 or 19,200 bps to operate the SCI properly. Table 18.6 shows host transfer bit rates and system clock frequencies for which automatic adjustment of the LSI bit rate is possible. The boot program should be executed within this system clock range. Table 18.6 System Clock Frequencies for which Automatic Adjustment of LSI Bit Rate is Possible Host Bit Rate 4800 bps 9,600 bps 19,200 bps System Clock Frequency for Which Automatic Adjustment of LSI Bit Rate is Possible (MHz) 4 to 25 8 to 25 16 to 25 Notes: 1. Use a host bit rate setting of 4800, 9600, or 19200 bps only. No other setting should be used. 2. Although the H8/3052F may also perform automatic bit rate adjustment with bit rate and system clock combinations other than those shown in table 18.6, a degree of error will arise between the bit rates of the host and the H8/3052F, and subsequent transfer will not be performed normally. Therefore, only combinations of bit rate and system clock within the ranges shown in table 18.6 can be used for boot mode execution. Rev. 2.0, 03/01, page 580 of 822 On-Chip RAM Area Divisions in Boot Mode: In boot mode, the RAM area is divided into an area used by the boot program and an area to which the programming control program is transferred via the SCI, as shown in figure 18.8. The boot program area cannot be used until the execution state in boot mode switches to the programming control program transferred from the host. H'FFDF10 Boot program area H'FFE70F H'FFE710 Programming control program area H'FFFF0F Figure 18.8 RAM Areas in Boot Mode Notes: 1. The boot program area cannot be used until a transition is made to the execution state for the programming control program transferred to RAM. Note also that the boot program remains in this area of the on-chip RAM even after control branches to the programming control program. 2. In flash memory emulation by RAM, part (H'FE000 to H'FEFFF) of the user program transfer area is used as the area in which emulation is performed, and therefore the user program must not be transferred to this area. Notes on Using the Boot Mode 1. When this LSI comes out of reset in boot mode, it measures the low period the input at the SCI's RXD1 pin. The reset should end with RXD1 high. After the reset ends, it takes about 100 states for this LSI to get ready to measure the low period of the RXD1 input. 2. If any data has been written to the flash memory (if all data is not H'FF), all flash memory blocks are erased when this mode is executed. Therefore, boot mode should be used for initial on-board programming, or for forced recovery if the program to be activated in user program mode is accidentally erased and user program mode cannot be executed, for example. 3. Interrupts cannot be used during programming or erasing of flash memory. 4. The RXD1 and TXD1 pins should be pulled up on the board. Rev. 2.0, 03/01, page 581 of 822 5. This LSI terminates transmit and receive operations by the on-chip SCI(channel 1) (by clearing the RE and TE bits in serial control register (SCR)) before branching to the user program. However, the adjusted bit rate is held in the bit rate register (BRR). At this time, the TXD1 pin is in the high level output state (P9DDR P91DDR=1, P9DR P91DR=1). Before branching to the user program the value of the general registers in the CPU are also undefined. Therefore, the general registers must be initialized immediately after control branches to the user program. Since the stack pointer (SP) is implicitly used during subroutine call, etc., a stack area must be specified for use by the user program. There are no other internal I/O registers in which the initial value is changed. 6. Transition to the boot mode executes a reset-start of this LSI after setting the MD0 to MD2 and FWE pins according to the mode setting conditions shown in Table 18.5. At this time, this LSI latches the status of the mode pin inside the microcomputer to maintain 1 the boot mode status at the reset clear (startup with Low High) timing* . To clear boot mode, it is necessary to drive the FWE pin low during the reset, and then execute 1 reset release* . The following points must be noted: * Before making a transition from the boot mode to the regular mode, the microcomputer boot mode must be reset by reset input via the 5(6 pin. At this time, the 5(6 pin must be 3 hold at low level for at least 20 system clock. * * Do not change the input levels at the mode pins (MD2 to MD0) or the FWE pin while in boot mode. When making a mode transition, first enter the reset state by inputting a low level to the 5(6 pin. When a watchdog timer reset was generated in the boot mode, the microcomputer mode is not reset and the on-chip boot program is restarted regardless of the state of the mode pin. * Do not input low level to the FWE pin while the boot program is executing and when 2 programming/erasing flash memory. * 7. If the mode pin and FWE pin input levels are changed from 0 V to VCC or from VCC to 0V during a reset (while a low level is being input to the 5(6 pin), the microcomputer's operating mode will change. Therefore, since the state of the address dual port and bus control output signals (&6Q, 5', +:5, /:5) changes, use of these pins as output signals during reset must be disabled outside the microcomputer. Rev. 2.0, 03/01, page 582 of 822 H8/3052F-ZTAT CSn External memory, etc. MD2 MD1 MD0 FWE RES System control unit Figure 18.9 Recommended System Block Diagram Notes: 1. The mode pin and FWE pin input must satisfy the mode programming setup time (tMDS) relative to the reset clear timing. 2. For notes on FWE pin High/Low, see section 18.11, Notes on Flash Memory Programming/Erasing. 3. See section 4.2.2, Reset Sequence and 18.11, Notes on Flash Memory Programming/Erasing. The H8/3052F requires a minimum of 20 system clocks. 18.6.2 User Program Mode When set to the user program mode, this LSI can erase and program its flash memory by executing a user program. Therefore, on-chip flash memory on-board programming can be performed by providing a means of controlling FWE and supplying the write data on the board and providing a write program in a part of the program area. To select this mode, set the LSI to on-chip ROM enable modes 5, 6, and 7 and apply a high level to the FWE pin. In this mode, the peripheral functions, other than flash memory, are performed the same as in modes 5, 6, and 7. Since the flash memory cannot be read while it is being programmed/erased, place a programming program on external memory, or transfer the programming program to RAM area, and execute it in the RAM. Figure 18.10 shows the procedure for executing when transferred to on-chip RAM. During reset start, starting from the user program mode is possible. Rev. 2.0, 03/01, page 583 of 822 Procedure 1 MD2-MD0 = 101, 110, 111 The user writes a program that executes steps 3 to 8 in advance as shown below. 1. Sets the mode pin to an on-chip ROM enable mode (mode 5, 6, or 7). 2. Starts the CPU via reset. (The CPU can also be started from the user program mode by setting the FWE pin to High level during reset; that is, during the period the RES pin is a low level.) 3. Transfers the on-board programming program to RAM. 4 Branch to program in RAM 4. Branches to the program in RAM. 5. Sets the FWE pin to a high level.* (Switches to user program mode.) 5 FWE = high (user program mode) 6. After confirming that the FWE pin is a high level, executes the on-board programming program in RAM. This reprograms the user application program in flash memory. 7. At the end of reprograming, clears the SWE1 and SWE2 bit, and exits the user program mode by switching the FWE pin from a high level to a low level.* 8. Branches to, and executes, the user application program reprogrammed in flash memory. 2 Reset start 3 Transfer on-board programming program to RAM 6 Execute on-board programming program in RAM (flash memory reprogramming) 7 Input low level to FWE after SWE1 and SWE2 bits clear (user program mode exit) 8 Execute user application program in flash memory Note: * For notes on FWE pin High/Low, see section 18.11, Notes on Flash Memory Programming/Erasing. Figure 18.10 User Program Mode Execution Procedure (Example) Note: Normally do not apply a high level to the FWE pin. To prevent erroneous programming or erasing in the event of program runaway, etc., apply a high level to the FWE pin only when programming/erasing flash memory (including flash memory emulation by RAM). If program runaway, etc. causes overprogramming or overerasing of flash memory, the memory cells will not operate normally. Also, while a high level is applied to the FWE pin, the watchdog timer should be activated to prevent overprogramming or overerasing due to program runaway, etc. Rev. 2.0, 03/01, page 584 of 822 18.7 Programming/Erasing Flash Memory A software method, using the CPU, is employed to program and erase flash memory in the onboard programming modes. There are four flash memory operating modes: program mode, erase mode, program-verify mode, and erase-verify mode. Transitions to these modes are made by setting the PSU1, ESU1, P1, E1, PV1, and EV1 bits in FLMCR1 for addresses H'00000 to H'3FFFF, or the PSU2, ESU2, P2, E2, PV2, and EV2 bits in FLMCR2 for addresses H'40000 to H'7FFFF. The flash memory cannot be read while it is being written or erased. Install the program to control flash memory programming and erasing (programming control program) in the on-chip RAM, in external memory, or in flash memory outside the address area, and execute the program from there. See section 18.1, Notes on Flash Memory Programming/Erasing, for points to be noted when programming or erasing the flash memory. In the following operation descriptions, wait times after setting or clearing individual bits in FLMCR1 and FLMCR2 are given as parameters; for details of the wait times, see section 21.2.5, Flash Memory Characteristics. Notes: 1. Operation is not guaranteed if bits SWE1, ESU1, PSU1, EV1, PV1, E1, and P1 of FLMCR1 and bits SWE2, ESU2, PSU2, EV2, PV2, E2 and P2 of FLMCR2 are set/reset by a program in flash memory in the corresponding address areas. 2. When programming or erasing, set FWE to 1 (programming/erasing will not be executed if FWE = 0). 3. Programming should be performed in the erased state. Do not perform additional programming on previously programmed addresses. 4. Do not program addresses H'00000 to H'3FFFF and H'40000 to H'7FFFF simultaneously. Operation is not guaranteed if this is done. Rev. 2.0, 03/01, page 585 of 822 *3 E1(2) = 1 Erase setup state E1(2) = 0 Normal mode Erase mode *1 FWE = 1 FWE = 0 *2 ES U1 (2 ES )= U1 1 (2 )= 0 E (2 V1 )= 1 )= 0 EV 1(2 Erase-verify mode On-board SWE1(2) = 1 Software programming mode programming Software programming enable disable state SWE1(2) = 0 state PS U1 (2) PS =1 =0 *4 P1(2) = 1 Program setup state P1(2) = 0 Program mode U1 (2) PV 1( 2) = 1 2) = 0 Program-verify mode Notes: In order to perform a normal read of flash memory, SWE must be cleared to 0. Also note that verify-reads can be performed during the programming/erasing process. 1. : Normal mode : On-board programming mode 2. Do not make a state transition by setting or clearing multiple bits simultaneously. 3. After a transition from erase mode to the erase setup state, do not enter erase mode without passing through the software programming enable state. 4. After a transition from program mode to the program setup state, do not enter program mode without passing through the software programming enable state. Figure 18.11 State Transitions Caused by FLMCR1 and FLMCR2 Bit Settings PV 1( Rev. 2.0, 03/01, page 586 of 822 18.7.1 Program Mode When writing data or programs to flash memory, the program/program-verify flowchart shown in figure 18.12 should be followed. Performing program operations according to this flowchart will enable data or programs to be written to flash memory without subjecting the device to voltage stress or sacrificing program data reliability. Programming should be carried out 128 bytes at a time. The wait times after bits are set or cleared in the flash memory control register (FLMCR1, FLMCR2) and the maximum number of programming operations (N) are shown in table 21.10 in section 21.2.5, Flash Memory Characteristics. Following the elapse of (tsswe) s or more after the SWE1 and SWE2 bits are set to 1 in FLMCR1 and FLMCR2, 128-byte data is written consecutively to the write addresses. The lower 8 bits of the first address written to must be H'00 and H'80, 128 consecutive byte data transfers are performed. The program address and program data are latched in the flash memory. A 128-byte data transfer must be performed even if writing fewer than 128 bytes; in this case, H'FF data must be written to the extra addresses. Next, the watchdog timer (WDT) is set to prevent overprogramming due to program runaway, etc. Set a value greater than (tspsu + tsp + tcp + tcpsu) s as the WDT overflow period. Preparation for entering program mode (program setup) is performed next by setting the PSU1 and PSU2 bits in FLMCR1 and FLMCR2. The operating mode is then switched to program mode by setting the P1 and P2 bits in FLMCR1 and FLMCR2 after the elapse of at least (tspsu) s. The time during which the P1 and P2 bits are set is the flash memory programming time. Make a program setting so that the time for one programming operation is within the range of (tsp) s. The wait time after P1 and P2 bits setting must be changed according to the number of reprogramming loops. For details, see section 21.2.5, Flash Memory Characteristics. Rev. 2.0, 03/01, page 587 of 822 18.7.2 Program-Verify Mode In program-verify mode, the data written in program mode is read to check whether it has been correctly written in the flash memory. After the elapse of the given programming time, clear the P1 and P2 bits in FLMCR1 and FLMCR2, then wait for at least (tcp) s before clearing the PSU1 and PSU2 bits to exit program mode. After exiting program mode, the watchdog timer setting is also cleared. The operating mode is then switched to program-verify mode by setting the PV1 and PV2 bits in FLMCR1 and FLMCR2. Before reading in program-verify mode, a dummy write of H'FF data should be made to the addresses to be read. The dummy write should be executed after the elapse of (tspv ) s or more. When the flash memory is read in this state (verify data is read in 16-bit units), the data at the latched address is read. Wait at least (tspvr) s after the dummy write before performing this read operation. Next, the originally written data is compared with the verify data, and reprogram data is computed (see figure 18.12) and transferred to RAM. After verification of 128 bytes of data has been completed, exit program-verify mode, wait for at least (tcpv) s, then determine whether 128-byte programming has finished. If reprogramming is necessary, set program mode again, and repeat the program/program-verify sequence as before. The maximum value for repetition of the program/program-verify sequence is indicated by the maximum programming count (N). Leave a wait time of at least (tcswe) s after clearing SWE1 or SWE2. 18.7.3 Notes on Program/Program-Verify Procedure 1. The program/program-verify procedure for the H8/3052F is a 128-byte-unit programming algorithm. In order to perform 128-byte-unit programming, the lower 8 bits of the write start address must be H'00 or H'80. 2. When performing continuous writing of 128-byte data to flash memory, byte-unit transfer should be used. 128-byte data transfer is necessary even when writing fewer than 128 bytes of data. H'FF data must be written to the extra addresses. 3. Verify data is read in word units. 4. The write pulse is applied and a flash memory write executed while the P1 bit in FLMCR1 or the P2 bit in FLMCR2 is set. In the H8/3052F, write pulses should be applied as follows in the program/program-verify procedure to prevent voltage stress on the device and loss of write data reliability. a. After write pulse application, perform a verify-read in program-verify mode and apply a write pulse again for any bits read as 1 (reprogramming processing). When all the 0-write bits in the 128-byte write data are read as 0 in the verify-read operation, the program/program-verify procedure is completed. In the H8/3052F, the number of loops in reprogramming processing is guaranteed not to exceed the maximum programming count (N). Rev. 2.0, 03/01, page 588 of 822 b. After write pulse application, a verify-read is performed in program-verify mode, and programming is judged to have been completed for bits read as 0. The following processing is necessary for programmed bits. When programming is completed at an early stage in the program/program-verify procedure: If programming is completed in the 1st to 6th reprogramming processing loop, additional programming should be performed on the relevant bits. Additional programming should only be performed on bits which first return 0 in a verify-read in certain reprogramming processing. When programming is completed at a late stage in the program/program-verify procedure: If programming is completed in the 7th or later reprogramming processing loop, additional programming is not necessary for the relevant bits. c. If programming of other bits is incomplete in the 128 bytes, reprogramming process should be executed. If a bit for which programming has been judged to be completed is read as 1 in a subsequent verify-read, a write pulse should again be applied to that bit. 5. The period for which the P1 bit in FLMCR1 or the P2 bit in FLMCR2 is set (the write pulse width) should be changed according to the degree of progress through the program/program-verify procedure. For detailed wait time specifications, see section 21.2.5, Flash Memory Characteristics. Table 18.7 Wait Time after P Bit Setting Item Wait time after P bit setting Symbol tsp Conditions When reprogramming loop count (n) is 1 to 6 When reprogramming loop count (n) is 7 or more In case of additional programming processing* Symbol tsp30 tsp200 tsp10 Note: * Additional programming processing is necessary only when the reprogramming loop count (n) is 1 to 6. 6. The program/program-verify flowchart for the H8/3052F is shown in figure 18.12. To cover the points noted above, bits on which reprogramming processing is to be executed, and bits on which additional programming is to be executed, must be determined as shown below. Since reprogram data and additional-programming data vary according to the progress of the programming procedure, it is recommended that the following data storage areas (128 bytes each) be provided in RAM. Rev. 2.0, 03/01, page 589 of 822 Table 18.8 Reprogram Data Computation Table Result of Verify-Read after Write Pulse (X) Application (V) Result of Operation 0 1 0 1 1 0 1 1 (D) 0 0 1 1 Comments Programming completed: reprogramming processing not to be executed Programming incomplete: reprogramming processing to be executed Still in erased state: no action Source data of bits on which programming is executed: (D) Data of bits on which reprogramming is executed: (X) Table 18.9 Additional-Programming Data Computation Table Result of Verify-Read after Write Pulse (Y) Application (V) Result of Operation 0 0 X 0 Comments Programming by write pulse application judged to be completed: additional programming processing to be executed Programming by write pulse application incomplete: additional programming processing not to be executed Programming already completed: additional programming processing not to be executed Still in erased state: no action 0 1 1 1 1 0 1 1 1 Data of bits on which additional programming is executed: (Y) Data of bits on which reprogramming is executed in a certain reprogramming loop: (X') 7. It is necessary to execute additional programming processing during the course of the H8/3052F program/program-verify procedure. However, once 128-byte-unit programming is finished, additional programming should not be carried out on the same address area. When executing reprogramming, an erase must be executed first. Note that normal operation of reads, etc., is not guaranteed if additional programming is performed on addresses for which a program/program-verify operation has finished. Rev. 2.0, 03/01, page 590 of 822 Write pulse application subroutine Start of programming START Set SWE1 (2) bit in FLMCR1 (2) Wait (tsswe) s Sub-Routine Write Pulse WDT enable Set PSU1 (2) in FLMCR1(2) Wait (tspsu) s Set P1 (2) bit in FLMCR1 (2) Wait (tsp) s Clear P1 (2) bit in FLMCR1 (2) Wait (tcp) s Clear PSU1 (2) bit in FLMCR1 (2) Wait (tcpsu) s Disable WDT Perform programming in the erased state. Do not perform additional programming on previously programmed addresses. *7 *4 *7 Store 128-byte program data in program data area and reprogram data area n= 1 m= 0 *5*7 Write 128-byte data in RAM reprogram data area consecutively to flash memory *1 Sub-Routine-Call *7 Write pulse See Note 6 for pulse width Set PV1 (2) bit in FLMCR1 (2) Wait (tspv) s H'FF dummy write to verify address *7 *7 Wait (tspvr) s End Sub Increment address Note 6: Write Pulse Width Number of Writes n Write Time (tsp) sec Write data = verify data? Read verify data *7 *2 NG m= 1 NG nn+1 1 2 3 4 5 6 7 8 9 10 11 12 13 30 30 30 30 30 30 200 200 200 200 200 200 200 OK 6n? OK Additional-programming data computation Transfer additional-programming data to additional-programming data area Reprogram data computation *4 *3 *4 Transfer reprogram data to reprogram data area 128-byte data verification completed? NG 998 999 1000 200 200 200 OK Clear PV1 (2) bit in FLMCR1 (2) Reprogram Wait (tcpv) s 6n? NG Note: Use a 10 s write pulse for additional programming. *7 RAM Program data storage area (128 bytes) OK Successively write 128-byte data from additional1 programming data area in RAM to flash memory * Sub-Routine-Call Write Pulse (Additional programming) Reprogram data storage area (128 bytes) m= 0 ? NG n N? *7 NG Additional-programming data storage area (128 bytes) OK Clear SWE1 (2) bit in FLMCR1 (2) Wait (tcswe) s End of programming OK Clear SWE1 (2) bit in FLMCR1 (2) Wait (tcswe) s Programming failure *7 Notes: 1. Data transfer is performed by byte transfer. The lower 8 bits of the first address written to must be H'00 or H'80. A 128-byte data transfer must be performed even if writing fewer than 128 bytes; in this case, H'FF data must be written to the extra addresses. 2. Verify data is read in 16-bit (W) units. 3. Reprogram data is determined by the operation shown in the table below (comparison between the data stored in the program data area and the verify data). Bits for which the reprogram data is 0 are programmed in the next reprogramming loop. Therefore, even bits for which programming has been completed will be subjected to programming once again if the result of the subsequent verify operation is NG. 4. A 128-byte area for storing program data and a 128-byte area for storing reprogram data must be provided in RAM. The contents of the reprogram data area are modified as programming proceeds. 5. A write pulse of 30 s or 200 s should be applied according to the progress of the programming operation. See Note 6 for the pulse widths. When writing of additionalprogramming data is executed, a 10 s write pulse should be applied. Reprogram data X' means reprogram data when the write pulse is applied. 7. The wait times and value of N are shown in section 21.2.5, Flash Memory. Reprogram Data Computation Table Original Data Verify Data Reprogram Data Additional-Programming Data Computation Table (X) 1 0 1 1 Still in erased state; no action Comments Programming completed Programming incomplete; reprogram (D) 0 0 1 1 (V) 0 1 0 1 Reprogram Data (X') 0 0 1 1 Verify Data Additional(V) Programming Data (Y) 0 1 0 1 0 1 1 1 Comments Additional programming to be executed Additional programming not to be executed Additional programming not to be executed Additional programming not to be executed Figure 18.12 Program/Program-Verify Flowchart (128-Byte Programming) Rev. 2.0, 03/01, page 591 of 822 18.7.4 Erase Mode To erase an individual flash memory block, follow the erase/erase-verify flowchart (single-block erase) shown in figure 18.13. The wait times after bits are set or cleared in the flash memory control register (FLMCR1, FLMCR2) and the maximum number of erase operations (N) are shown in table 21.10 in section 21.2.5, Flash Memory Characteristics. To erase flash memory contents, make a 1-bit setting for the flash memory area to be erased in erase block register 1 and 2 (EBR1, EBR2) at least (tsswe) s after setting the SWE1 and SWE2 bits to 1 in FLMCR1 and FLMCR2. Next, the watchdog timer (WDT) is set to prevent overerasing due to program runaway, etc. Set a value greater than (tse) ms + (tsesu + tce + tcesu) s as the WDT overflow period. Preparation for entering erase mode (erase setup) is performed next by setting the ESU1 and ESU2 bits in FLMCR1 and FLMCR2. The operating mode is then switched to erase mode by setting the E1 and E2 bits in FLMCR1 and FLMCR2 after the elapse of at least (tsesu) s. The time during which the E1 and E2 bits are set is the flash memory erase time. Ensure that the erase time does not exceed (tse) ms. Note: With flash memory erasing, preprogramming (setting all memory data in the memory to be erased to all 0) is not necessary before starting the erase procedure. 18.7.5 Erase-Verify Mode In erase-verify mode, data is read after memory has been erased to check whether it has been correctly erased. After the elapse of the fixed erase time, clear the E1 and E2 bits in FLMCR1 and FLMCR2, then wait for at least (tce) s before clearing the ESU1 and ESU2 bits to exit erase mode. After exiting erase mode, the watchdog timer setting is also cleared. The operating mode is then switched to erase-verify mode by setting the EV1 and EV2 bits in FLMCR1 and FLMCR2. Before reading in erase-verify mode, a dummy write of H'FF data should be made to the addresses to be read. The dummy write should be executed after the elapse of (tsev) s or more. When the flash memory is read in this state (verify data is read in 16-bit units), the data at the latched address is read. Wait at least (tsevr) s after the dummy write before performing this read operation. If the read data has been erased (all 1), a dummy write is performed to the next address, and erase-verify is performed. If the read data is unerased, set erase mode again, and repeat the erase/erase-verify sequence as before. The maximum value for repetition of the erase/erase-verify sequence is indicated by the maximum erase count (N). When verification is completed, exit erase-verify mode, and wait for at least (tcev) s. If erasure has been completed on all the erase blocks, clear bits SWE1 and SWE2 in FLMCR1 and FLMCR2, and leave a wait time of at least (tcswe) s. If erasing multiple blocks, set a single bit in EBR1/EBR2 for the next block to be erased, and repeat the erase/erase-verify sequence as before. Rev. 2.0, 03/01, page 592 of 822 Start *1 Perform erasing in block units. Set SWE1 (2) bit in FLMCR1 (2) Wait tsswe s n=1 Set EBR1 or EBR2 Enable WDT Set ESU1 (2) bit in FLMCR1 (2) Wait tsesu s Set E1 (2) bit in FLMCR1 (2) Wait tse ms Clear E1 (2) bit in FLMCR1 (2) Wait tce s Clear ESU1 (2) bit in FLMCR1 (2) Wait tcesu s Disable WDT Set EV1 (2) bit in FLMCR1 (2) Wait tsev s Set block start address as verify address *4 *4 *4 *3 *4 Start of erase *4 Erase halted *4 nn+1 H'FF dummy write to verify address Wait tsevr s Increment address Read verify data Verify data = all 1s? Yes No Last address of block? Yes Clear EV1 (2) bit in FLMCR1 (2) Wait tcev s *4 *4 *2 No Clear EV1 (2) bit in FLMCR1 (2) Wait tcev s *4 *4 n N? Yes Clear SWE1 (2) bit in FLMCR1 (2) *4 No Clear SWE1 (2) bit in FLMCR1 (2) Wait tcswe s End of erasing Wait tcswe s Erase failure *4 Notes: 1. 2. 3. 4. Prewriting (setting erase block data to all 0s) is not necessary. Verify data is read in 16-bit (W) units. Make only a single-bit specification in the erase block registers (EBR1 and EBR2). Two or more bits must not be set simultaneously. The wait times and the value of N are shown in section 21.2.5, Flash Memory Characteristics. Figure 18.13 Erase/Erase-Verify Flowchart (Single-Block Erase) Rev. 2.0, 03/01, page 593 of 822 18.8 Protection There are three kinds of flash memory program/erase protection: hardware protection, software protection, and error protection. 18.8.1 Hardware Protection Hardware protection refers to a state in which programming/erasing of flash memory is forcibly disabled or aborted. Hardware protection is reset by settings in flash memory control register 1 (FLMCR1), flash memory control register 2 (FLMCR2), erase block register 1 (EBR1), and erase block register 2 (EBR2). In the error-protected state, the FLMCR1, FLMCR2, EBR1, and EBR2 settings are retained; the P1 and P2 bits can be set, but a transition is not made to program mode or erase mode. (See table 18.10.) Rev. 2.0, 03/01, page 594 of 822 Table 18.10 Hardware Protection Functions Item FWE pin protection Description * When a low level is input to the FWE pin, FLMCR1, FLMCR2, (except bit FLER) EBR1, and EBR2 are initialized, and the program/ 5 erase-protected state is entered. * Program Erase No* 2 Verify* -- 1 No* 3 Reset/ standby protection * No In a power-on reset (including a WDT power-on reset) and in standby mode, FLMCR1, FLMCR2, EBR1, and EBR2 are initialized, and the program/erase-protected state is entered. In a reset via the 5(6 pin, the reset state is not entered unless the 5(6 pin is held low until oscillation stabilizes after powering on. In the case of a reset during operation, hold the 5(6 pin low for the 5(6 pulse width specified in the 6 AC Characteristics section. * No When a microcomputer operation error (error generation (FLER=1)) was detected while flash memory was being programmed/erased, error protection is enabled. At this time, the FLMCR1, FLMCR2, EBR1, and EBR2 settings are held, but programming/erasing is aborted at the time the error was generated. Error protection is released only by a reset via the 5(6 pin or a WDT reset, or in the hardware standby mode. No* 3 -- * Error protection * No* 3 Yes* 4 Notes: 1. 2. 3. 4. Two modes: program-verify and erase-verify. Excluding a RAM area overlapping flash memory. All blocks are unerasable and block-by-block specification is not possible. It is possible to perform a program-verify operation on the 128 bytes being programmed, or an erase-verify operation on the block being erased. 5. For details see section 18.11, Flash Memory Programming and Erasing Precautions. 6. See section 4.2.2, Reset Sequence, and section 18.11, Flash Memory Programming and Erasing Precautions. The H8/3052F requires at least 20 system clocks for a reset during operation. Rev. 2.0, 03/01, page 595 of 822 18.8.2 Software Protection Software protection can be implemented by setting the SWE1 bit in FLMCR1, the SWE2 bit in FLMCR2, erase block register 1 (EBR1), erase block register 2 (EBR2), and the RAMS bit in the RAM control register (RAMCR). When software protection is in effect, setting the P1 or E1 bit in flash memory control register 1 (FLMCR1), or the P2 or E2 bit in flash memory control register 2 (FLMCR2) does not cause a transition to program mode or erase mode. (See table 18.11.) Table 18.11 Software Protection Functions Item Block specification protection Description * Erase protection can be set for individual blocks by settings in erase block register 1 2 2 (EBR1)* and erase block register 2 (EBR2)* . However, programming protection is disabled. Setting EBR1 and EBR2 to H'00 places all blocks in the erase-protected state. Setting the RAMS bit to 1 in the RAM control register (RAMCR) places all blocks in the program/erase-protected state. No* 3 Program Erase -- No Verify* Yes 1 * Emulation protection Notes: 1. 2. 3. 4. * No* 4 Yes Two modes: program-verify and erase-verify. When not erasing, clear all EBR1, EBR2 bits to 0. A RAM area overlapping flash memory can be written to. All blocks are unerasable and block-by-block specification is not possible. Rev. 2.0, 03/01, page 596 of 822 18.8.3 Error Protection In error protection, an error is detected when H8/3052F runaway occurs during flash memory 1 programming/erasing* , or operation is not performed in accordance with the program/erase algorithm, and the program/erase operation is aborted. Aborting the program/erase operation prevents damage to the flash memory due to overprogramming or overerasing. If the H8/3052F malfunctions during flash memory programming/erasing, the FLER bit is set to 1 in FLMCR2 and the error protection state is entered. The FLMCR1, FLMCR2, EBR1, and EBR2 3 settings* are retained, but program mode or erase mode is aborted at the point at which the error occurred. Program mode or erase mode cannot be re-entered by re-setting the P1, P2, E1, or E2 bit. However, PV1, PV2, EV1 and EV2 bit setting is enabled, and a transition can be made to 2 verify mode.* FLER bit setting conditions are as follows: 1. When the flash memory of the relevant address area is read during programming/erasing (including vector read and instruction fetch) 2. Immediately after exception handling (excluding a reset) during programming/erasing 3. When a SLEEP instruction (including software standby) is executed during programming/erasing 4. When the CPU releases the bus to the DMAC during programming/erasing Error protection is released only by a power-on reset and in hardware standby mode. Notes: 1. State in which the P1 bit or E1 bit in FLMCR1, or the P2 bit or E2 bit in FLMCR2, is set to 1. Note that NMI input is disabled in this state. 2. It is possible to perform a program-verify operation on the 128 bytes being programmed, or an erase-verify on the block being erased. 3. FLMCR1, FLMCR2, EBR1, and EBR2 can be written to. However, the registers are initialized if a transition is made to software standby mode while in the error-protected state. Rev. 2.0, 03/01, page 597 of 822 Figure 18.14 shows the flash memory state transition diagram. Memory read verify mode RD VF PR ER FLER = 0 P = 1 or E=1 P = 0 and E=0 Re set o or r ha sof rdw Re twa a re re st sta set re a sta nd lea nd ndby by by rel se an ea d sta nd se a hard by n rel d so ware ea se ftware Program mode Erase mode RD VF PR ER FLER = 0 Reset or hardware standby Er (so ror o ftw ccu ar e s rren tan ce db y) Reset or standby (hardware protection) RD VF PR ER INIT FLER = 0 Error occurrence ha or et y s Re ndb sta rdw are Reset or hardware standby Error protection mode RD VF PR ER FLER = 1 Software standby mode Software standby mode release Error protection mode (software standby) RD VF PR ER INIT FLER = 1 Legend RD: Memory read possible VF: Verify-read possible PR: Programming possible ER: Erasing possible RD: VF: PR: ER: INIT: Memory read not possible Verify-read not possible Programming not possible Erasing not possible Register initialization state Figure 18.14 Flash Memory State Transitions (Modes 5, 6, and 7 (on-chip ROM enabled), high level applied to FWE pin) Rev. 2.0, 03/01, page 598 of 822 18.8.4 NMI Input Disable Conditions While flash memory is being programed/erased and the boot program is executing in the boot 1 mode (however, period up to branching to on-chip RAM area)* , NMI input is disabled because the programming/erasing operations have priority. This is done to avoid the following operation states: 1. Generation of an NMI input during programming/erasing violates the program/erase algorithms and normal operation can not longer be assured. 2. Vector-read cannot be carried out normally* during NMI exception handling during programming/erasing and the microcomputer runs away as a result. 3. If an NMI input is generated during boot program execution, the normal boot mode sequence cannot be executed. Therefore, this LSI has conditions that exceptionally disable NMI inputs only in the on-board programming mode. However, this does not assure normal programming/erasing and microcomputer operation. Thus, in the FWE application state, all requests, including NMI, inside and outside the microcomputer, exception handling, and bus release must be restricted. NMI input is also 3 disabled* in the error-protected state and when the P1 bit or E1 bit in FLMCR1, or the P2 bit or E2 bit in FLMCR2, is retained during flash memory emulation by RAM. Notes: 1. Indicates the period up to branching to the on-chip RAM boot program area (H'FFDF10). (This branch occurs immediately after user program transfer was completed.) Therefore, after branching to RAM area, NMI input is enabled in states other than the program/erase state. Thus, interrupt requests inside and outside the microcomputer must be disabled until initial writing by user program (writing of vector table and NMI processing program, etc.) is completed. 2. In this case, vector read is not performed normally for the following two reasons: a. The correct value cannot be read even by reading the flash memory during programming/erasing. (Value is undefined.) b. If a value has not yet been written to the NMI vector table, NMI exception handling will not be performed correctly. 3. When the emulation function is used, NMI input is prohibited when the P1 bit or E1 bit in FLMCR1, or the P2 bit or E2 bit in FLMCR2, is set to 1, in the same way as with normal programming and erasing. The P1 and E1 bits and the P2 and E2 bits are cleared by a reset (including a watchdog timer reset), in standby mode, when a high level is not being input to the FWE pin, or when the SWE1 bit in FLMCR1 is 0, or the SWE2 bit in FLMCR2 is 0, while a high level is being input to the FWE pin. Rev. 2.0, 03/01, page 599 of 822 2 18.9 Flash Memory Emulation in RAM Making a setting in the RAM control register (RAMCR) enables part of RAM to be overlapped onto the flash memory area so that data to be written to flash memory can be emulated in RAM in real time. After the RAMCR setting has been made, accesses can be made from the flash memory area or the RAM area overlapping flash memory. Emulation can be performed in user mode and user program mode. Figure 18.15 shows an example of emulation of real-time flash memory programming. Start of emulation program Set RAMCR Write tuning data to overlap RAM Execute application program No Tuning OK? Yes Clear RAMCR Write to flash memory emulation block End of emulation program Figure 18.15 Flowchart for Flash Memory Emulation in RAM Rev. 2.0, 03/01, page 600 of 822 This area can be accessed from both the RAM area and flash memory area H'00000 EB0 H'01000 EB1 H'02000 EB2 H'03000 EB3 H'04000 EB4 H'05000 EB5 H'06000 EB6 H'07000 EB7 H'08000 H'FDF10 H'FE000 Flash memory EB8 to EB15 On-chip RAM H'FFF0F H'7FFFF H'FEFFF Figure 18.16 Example of RAM Overlap Operation Example in which Flash Memory Block Area EB0 is Overlapped 1. Set bits RAMS, RAM2 to RAM0 in RAMCR to 1, 0, 0, 0, to overlap part of RAM onto the area (EB0) for which real-time programming is required. 2. Real-time programming is performed using the overlapping RAM. 3. After the program data has been confirmed, clear the RAMS bit to release RAM overlap. 4. Write the data written in the overlapping RAM into the flash memory space (EB0). Notes: 1. When the RAMS bit is set to 1, program/erase protection is enabled for all blocks regardless of the value of RAM2 to RAM0 (emulation protection). In this state, setting the P1 or E1 bit in flash memory control register 1 (FLMCR1), or the P2 or E2 bit in flash memory control register 2 (FLMCR2), will not cause a transition to program mode or erase mode. When actually programming or erasing a flash memory area, the RAMS bit should be cleared to 0. 2. A RAM area cannot be erased by execution of software in accordance with the erase algorithm while flash memory emulation in RAM is being used. 3. Block area EB0 includes the vector table. When performing RAM emulation, the vector table is needed by the overlap RAM. Rev. 2.0, 03/01, page 601 of 822 4. Flash write enable (FWE) application and releasing As in on-board programming mode, care is required when applying and releasing FWE to prevent erroneous programming or erasing. To prevent erroneous programming and erasing due to program runaway during FWE application, in particular, the watchdog timer should be set when the P1 or E1 bit in FLMCR1, or the P2 or E2 bit in FLMCR2, is set to 1, even while the emulation function is being used. For details, see section 18.11, Flash Memory Programming and Erasing Precautions. 5. When the emulation function is used, NMI input is prohibited when the P1 bit or E1 bit in FLMCR1, or the P2 bit or E2 bit in FLMCR2, is set to 1, in the same way as with normal programming and erasing. The P1 and E1 bits and the P2 and E2 bits are cleared by a reset (including a watchdog timer reset), in standby mode, when a high level is not being input to the FWE pin, or when the SWE1 bit in FLMCR1 is 0, or the SWE2 bit in FLMCR2 is 0, while a high level is being input to the FWE pin. 18.10 Flash Memory PROM Mode The H8/3052F has a PROM mode as well as the on-board programming modes for programming and erasing flash memory. In PROM mode, the on-chip ROM can be freely programmed using a general-purpose PROM writer that supports the Hitachi microcomputer device type with 512kbyte on-chip flash memory. 18.10.1 Socket Adapters and Memory Map In PROM mode using a PROM writer, memory reading (verification) and writing and flash memory initialization (total erasure) can be performed. For these operations, a special socket adapter is mounted in the PROM writer. The socket adapter product codes are given in table 18.12. In the H8/3052F PROM mode, only the socket adapters shown in this table should be used. Rev. 2.0, 03/01, page 602 of 822 Table 18.12 H8/3052F Socket Adapter Product Codes Product Code HD64F3052F HD64F3052BF HD64F3052BVF HD64F3052TE HD64F3052BTE HD64F3052BVTE HD64F3052F HD64F3052BF HD64F3052BVF HD64F3052TE HD64F3052BTE HD64F3052BVTE 100-pin TQFP (TFP-100B) HF306BT100D4001 100-pin QFP (FP-100B) HF306BQ100D4001 Data IO Japan 100-pin TQFP (TFP-100B) ME3064ESNF1H Package 100-pin QFP (FP-100B) Socket Adapter Product Code ME3064ESHF1H Manufacturer Minato Electronics Figure 18.17 shows the memory map in PROM mode. MCU mode H'000000 H8/3052F PROM mode H'00000 On-chip ROM H'07FFFF H'7FFFF Figure 18.17 Memory Map in PROM Mode 18.10.2 Notes on Use of PROM Mode 1. A write to a 128-byte programming unit in PROM mode should be performed once only. Erasing must be carried out before reprogramming an address that has already been programmed. 2. When using a PROM writer to reprogram a device on which on-board programming/erasing has been performed, it is recommended that erasing be carried out before executing programming. 3. The memory is initially in the erased state when the device is shipped by Hitachi. For samples for which the erasure history is unknown, it is recommended that erasing be executed to check and correct the initialization (erase) level. Rev. 2.0, 03/01, page 603 of 822 4. 5. The H8/3052F does not support a product identification mode as used with general-purpose EPROMs, and therefore the device name cannot be set automatically in the PROM writer. Refer to the instruction manual provided with the socket adapter, or other relevant documentation, for information on PROM writers and associated program versions that are compatible with the PROM mode of the H8/3052F. 18.11 Notes on Flash Memory Programming/Erasing The following describes notes when using the on-board programming mode, RAM emulation function, and PROM mode. 1. Program/erase with the specified voltage and timing. Applied voltages in excess of the rating can permanently damage the device. Use a PROM writer that supports the Hitachi 512 kbytes flash memory on-board microcomputer device type. If the wrong device type is set, a high level may be input to the FWE pin, resulting in permanent damage to the device. 2. Notes on powering on/powering off (See figures 18.18 to 18.20) Input a high level to the FWE pin after verifying Vcc. Before turning off Vcc, set the FWE pin to a low level. When powering on and powering off the Vcc power supply, fix the FWE pin low and set the flash memory to the hardware protection mode. Be sure that the powering on and powering off timing is satisfied even when the power is turned off and back on in the event of a power interruption, etc. If this timing is not satisfied, microcomputer runaway, etc., may cause overprogramming or overerasing and the memory cells may not operate normally. 3. Notes on FWE pin High/Low switching (See figures 18.18 to 18.20) Input FWE in the state microcomputer operation is verified. If the microcomputer does not satisfy the operation confirmation state, fix the FWE pin low to set the protection mode. To prevent erroneous programming/erasing of flash memory, note the following in FWE pin High/Low switching: a. Apply an input to the FWE pin after the Vcc voltage has stabilized within the rated voltage. If an input is applied to the FWE pin when the microcomputer Vcc voltage does not satisfy the rated voltage, flash memory may be erroneously programmed or erased because the microcomputer is in the unconfirmed state. b. Apply an input to the FWE pin when the oscillation has stabilized (after the oscillation stabilization time). When turning on the Vcc power, apply an input to the FWE pin after holding the 5(6 pin at a low level during the oscillation stabilization time (tosc1 = 20ms). Do not apply an input to the FWE pin when oscillation is stopped or unstable. c. In the boot mode, perform FWE pin High/Low switching during reset. Rev. 2.0, 03/01, page 604 of 822 In transition to the boot mode, input FWE = High level and set MD2 to MD0 while the 5(6 input is low. At this time, the FWE and MD2 to MD0 inputs must satisfy the mode programming setup time (tMDS) relative to the reset clear timing. The mode programming setup time is necessary for 5(6 reset timing even in transition from the boot mode to another mode. In reset during operation, the 5(6 pin must be held at a low level for at least 20 system clocks. d. In the user program mode, FWE = High/Low switching is possible regardless of the 5(6 input. FWE input switching is also possible during program execution on flash memory. e. Apply an input to FWE when the program is not running away. When applying an input to the FWE pin, the program execution state must be supervised using a watchdog timer, etc. f. Release FWE pin input only when the SWE1, ESU1, PSU1, EV1, PV1, E1, and P1 bits in FLMCR1, and the SWE2, ESU2, PSU2, EV2, PV2, E2, and P2 bits in FLMCR2, are cleared. Do not erroneously set any of bits SWE1, ESU1, PSU1, EV1, PV1, E1, P1, SWE2, ESU2, PSU2, EV2, PV2, E2, or P2 when applying or releasing FWE. 4. Do not input a constant high level to the FWE pin. To prevent erroneous programming/erasing in the event of program runaway, etc., input a high level to the FWE pin only when programming/erasing flash memory (including flash memory emulation by RAM). Avoid system configurations that constantly input a high level to the FWE pin. Handle program runaway, etc. by starting the watchdog timer so that flash memory is not overprogrammed/overerased even while a high level is input to the FWE pin. 5. Program/erase the flash memory in accordance with the recommended algorithms. The recommended algorithms can program/erase the flash memory without applying voltage stress to the device or sacrificing the reliability of the program data. When setting the PSU1 and ESU1 bits in FLMCR1, or PSU2 and ESU2 bits in FLMCR2 set the watchdog timer for program runaway, etc. Accesses to flash memory by means of an MOV instruction, etc., are prohibited while bit P1/P2 or bit E1/E2 is set. 6. Do not set/clear the SWE bit while a program is executing on flash memory. Before performing flash memory program execution or data read, clear the SWE bit. If the SWE bit is set, the flash data can be reprogrammed, but flash memory cannot be accessed for purposes other than verify (verify during programming/erase). Similarly perform flash memory program execution and data read after clearing the SWE bit even when using the RAM emulation function with a high level input to the FWE pin. However, RAM area that overlaps flash memory space can be read/programmed whether the SWE bit is set or cleared. 7. Do not use an interrupt during flash memory programming or erasing. Rev. 2.0, 03/01, page 605 of 822 Since programming/erase operations (including emulation by RAM) have priority when a high level is input to the FWE pin, disable all interrupt requests, including NMI. 8. Do not perform additional programming. Reprogram flash memory after erasing. With on-board programming, program to 128-byte programming unit blocks one time only. Program to 128-byte programming unit blocks one time only even in the writer mode. Erase all the programming unit blocks before reprogramming. 9. Before programming, check that the chip is correctly mounted in the PROM programmer. Overcurrent damage to the device can result if the index marks on the PROM programmer socket, socket adapter, and chip are not correctly aligned. 10. Do not touch the socket adapter or chip during programming. Touching either of these can cause contact faults and write errors. Programming and erase possible Wait time: x tOSC1 VCC Min 0 s FWE tMDS Min 200 ns Min 0 s MD2 to MD0*1 tMDS RES SWE1 (2) set SWE1(2) bit SWE1 (2) clear Flash memory access disabled period (x: Wait time after SWE1 (2) setting)*2 Flash memory reprogrammable period (Flash memory program execution and data read, other than verify, are disabled.) Notes: 1. Always fix the level by pulling down or pulling up the mode pins (MD2 to MD0) until powering off, except for mode switching. 2. See 21.2.5 Flash Memory Characteristics. Figure 18.18 Powering On/Off Timing (Boot Mode) Rev. 2.0, 03/01, page 606 of 822 Wait time: x Programming and erase possible tOSC1 VCC Min 0 s FWE tH MD2 to MD0*1 tMDS RES SWE1 (2) set SWE1(2) bit SWE1 (2) clear Flash memory access disabled period (x: Wait time after SWE1(2) setting)*2 Flash memory reprogrammable period (Flash memory program execution and data read, other than verify, are disabled.) Notes: 1. Always fix the level by pulling down or pulling up the mode pins (MD2 to MD0) up to powering off, except for mode switching. 2. See 21.2.5 Flash Memory Characteristics. Figure 18.19 Powering On/Off Timing (User Program Mode) Rev. 2.0, 03/01, page 607 of 822 Wait time: x Programming and erase possible Programming and Programming Wait erase Wait and erase time: x possible time: x possible Programming Wait and erase time: x possible tOSC1 VCC Min 0 s tH FWE tMDS *2 tMDS MD2 to MD0 tMDS tRESW RES SWE1 (2) set SWE1 (2) clear SWE1 (2) bit Mode switching*1 Boot mode Mode User switching*1 mode User program mode User mode User program mode Flash memory access disabled time (x: Wait time after SWE1 (2) setting)*3 Flash memory reprogammable period (Flash memory program execution and data read, other than verify, are disabled.) Notes: 1. In transition to the boot mode and transition from the boot mode to another mode, mode switching via RES input is necessary. During this switching period (period during which a low level is input to the RES pin),the state of the address dual port and bus control output signals (AS, RD, WR) changes. Therefore, do not use these pins as output signals during this switching period. 2. When making a transition from the boot mode to another mode, the mode programming setup time tMDS relative to the RES clear timing is necessary. 3. See 21.2.5 Flash Memory Characteristics. Figure 18.20 Mode Transition Timing (Example: Boot mode User mode User program mode) Rev. 2.0, 03/01, page 608 of 822 Section 19 Clock Pulse Generator 19.1 Overview The H8/3052F has a built-in clock pulse generator (CPG) that generates the system clock () and other internal clock signals (/2 to /4096). After duty adjustment, a frequency divider divides the clock frequency to generate the system clock (). The system clock is output at the pin*1 and furnished as a master clock to prescalers that supply clock signals to the on-chip supporting modules. Frequency division ratios of 1/1, 1/2, 1/4, and 1/8 can be selected*2 for the frequency divider by settings in a division control register (DIVCR). Power consumption in the chip is reduced in almost direct proportion to the frequency division ratio. Notes: 1. Usage of the pin differs depending on the chip operating mode and the PSTOP bit setting in the module standby control register (MSTCR). For details, see section 20.7, System Clock Output Disabling Function. 2. The division ratio of the frequency divider can be changed dynamically during operation. The clock output at the pin also changes when the division ratio is changed. The frequency output at the pin is shown below. = EXTAL x n where, EXTAL: Frequency of crystal resonator or external clock signal n: Frequency division ratio (n = 1/1, 1/2, 1/4, or 1/8) Rev. 2.0, 03/01, page 609 of 822 19.1.1 Block Diagram Figure 19.1 shows a block diagram of the clock pulse generator. CPG XTAL Oscillator EXTAL Duty adjustment circuit Frequency divider Prescalers Division control register Data bus /2 to /4096 Figure 19.1 Block Diagram of Clock Pulse Generator Rev. 2.0, 03/01, page 610 of 822 19.2 Oscillator Circuit Clock pulses can be supplied by connecting a crystal resonator, or by input of an external clock signal. 19.2.1 Connecting a Crystal Resonator Circuit Configuration: A crystal resonator can be connected as in the example in figure 19.2. The damping resistance Rd should be selected according to table 19.1(1). An AT-cut parallelresonance crystal should be used. C L1 EXTAL XTAL Rd C L2 Figure 19.2 Connection of Crystal Resonator (Example) If a crystal resonator with a frequency higher than 20MHz is connected,the external load capacitance values in table 20.1(2)should not exceed 10[pF] Also,in order to improve the accuracy of the oscillation frequency a thorough study of oscillation matching evaluation etc. should be carried out when deciding the circuit constants. Table 19.1(1) Damping Resistance 2 Value Rd () Damping Resistance Value Frequency f (MHz) 2 < f 4 4 < f 8 8 < f 10 10 < f 13 13 < f 16 16 < f 18 500 200 100 0 0 18 < f 25 20 < f 25 0 0 1k 1k Note: A crystal resonator between 2 MHz and 25 MHz can be used. If the chip is to be operated at less than 2 MHz, the on-chip frequency divider should be used. (A crystal resonator of less than 2 MHz cannot be used.) Table 19.1(2) External Capacitance Values 5V operation 3V operation External Capacitance Values Frequency f (MHz) CL1 = CL2 (pF) 20 < f 25 10 2 f 20 10 to 22 2 f 13 10 to 22 13 f 25 10 Rev. 2.0, 03/01, page 611 of 822 Crystal Resonator: Figure 19.3 shows an equivalent circuit of the crystal resonator. The crystal resonator should have the characteristics listed in table 19.2. CL L XTAL Rs EXTAL C0 AT-cut parallel-resonance type Figure 19.3 Crystal Resonator Equivalent Circuit Table 19.2 Crystal Resonator Parameters Frequency (MHz) 2 Rs max () Co (pF) 500 7 pF max 4 120 8 80 10 70 12 60 16 50 18 40 20 40 25 40 Use a crystal resonator with a frequency equal to the system clock frequency (). Notes on Board Design: When a crystal resonator is connected, the following points should be noted: Other signal lines should be routed away from the oscillator circuit to prevent induction from interfering with correct oscillation. See figure 19.4. When the board is designed, the crystal resonator and its load capacitors should be placed as close as possible to the XTAL and EXTAL pins. Avoid C L2 XTAL Signal A Signal B H8/3052F EXTAL C L1 Figure 19.4 Example of Incorrect Board Design Rev. 2.0, 03/01, page 612 of 822 19.2.2 External Clock Input Circuit Configuration: An external clock signal can be input as shown in the examples in figure 19.5. If the XTAL pin is left open, the stray capacitance should not exceed 10 pF. If the stray capacitance at the XTAL pin exceeds 10 pF in configuration a, use configuration b instead and hold the clock high in standby mode. EXTAL External clock input XTAL Open a. XTAL pin left open EXTAL External clock input XTAL b. Complementary clock input at XTAL pin Figure 19.5 External Clock Input (Examples) Rev. 2.0, 03/01, page 613 of 822 External Clock: The external clock frequency should be equal to the system clock frequency () when not divided by the on-chip frequency divider. Table 19.3 shows the clock timing, and figure 19.6 shows the external clock input timing. Figure 19.7 shows the external clock output stabilization delay timing. When the appropriate external clock is input via the EXTAL pin, its waveform is corrected by the on-chip oscillator and duty adjustment circuit. The resulting stable clock is output to external devices after the external clock settling time (tDEXT) has passed after the clock input. The system must remain reset with the reset signal low during tDEXT, while the clock output is unstable. Table 19.3 Clock Timing VCC = 5.0 V 10% VCC = 3.0V to 3.6V Item External clock input low pulse width External clock input high pulse width External clock rise time External clock fall time Clock low pulse width Clock high pulse width External clock output settling delay time Symbol Min tEXL tEXH tEXr tEXf tCL tCH tDEXT* 15 15 -- -- 0.4 80 0.4 80 500 Max -- -- 5 5 0.6 -- 0.6 -- -- Unit ns ns ns ns tcyc ns tcyc ns s 5 MHz Figure 21.4 < 5 MHz 5 MHz < 5 MHz Figure 19.7 Test Conditions Figure 19.6 Note: * tDEXT includes 10 tcyc of 5(6 pulse width (tRESW). tEXH VCC x 0.7 EXTAL 0.3 V tEXr tEXf tEXL VCC x 0.5 Figure 19.6 External Clock Input Timing Rev. 2.0, 03/01, page 614 of 822 VCC 2.7 V VIH EXTAL (internal or external) tDEXT* Note: * tDEXT includes 10 tcyc of pulse width (tRESW). Figure 19.7 External Clock Output Settling Delay Timing 19.3 Duty Adjustment Circuit When the oscillator frequency is 5 MHz or higher, the duty adjustment circuit adjusts the duty cycle of the clock signal from the oscillator to generate the signal that becomes the system clock. 19.4 Prescalers The prescalers divide the system clock () to generate internal clocks (/2 to /4096). 19.5 Frequency Divider The frequency divider divides the duty-adjusted clock signal to generate the system clock (). The frequency division ratio can be changed dynamically by modifying the value in DIVCR, as described below. Power consumption in the chip is reduced in almost direct proportion to the frequency division ratio. The system clock generated by the frequency divider can be output at the pin. Rev. 2.0, 03/01, page 615 of 822 19.5.1 Register Configuration Table 19.4 summarizes the frequency division register. Table 19.4 Address* H'FF5D Frequency Division Register Name Division control register Abbreviation DIVCR R/W R/W Initial Value H'FC Note: * The lower 16 bits of the address are shown. 19.5.2 Division Control Register (DIVCR) DIVCR is an 8-bit readable/writable register that selects the division ratio of the frequency divider. Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 DIV1 0 R/W 0 DIV0 0 R/W Reserved bits Divide bits 1 and 0 These bits select the frequency division ratio DIVCR is initialized to H'FC by a reset and in hardware standby mode. It is not initialized in software standby mode. Bits 7 to 2--Reserved: Read-only bits, always read as 1. Bits 1 and 0--Divide (DIV1 and DIV0): These bits select the frequency division ratio, as follows. Bit 1: DIV1 0 1 Bit 0: DIV0 0 1 0 1 Frequency Division Ratio 1/1 1/2 1/4 1/8 (Initial value) Rev. 2.0, 03/01, page 616 of 822 19.5.3 Usage Notes The DIVCR setting changes the frequency, so note the following points. * Select a frequency division ratio that stays within the assured operation range specified for the clock cycle time tcyc in the AC electrical characteristics. Note that MIN = 2 MHz. Avoid settings that give system clock frequencies less than 2 MHz. * All on-chip module operations are based on . Note that the timing of timer operations, serial communication, and other time-dependent processing differs before and after any change in the division ratio. The waiting time for exit from software standby mode also changes when the division ratio is changed. For details, see section 20.4.3, Selection of Waiting Time for Exit from Software Standby Mode. Rev. 2.0, 03/01, page 617 of 822 Rev. 2.0, 03/01, page 618 of 822 Section 20 Power-Down State 20.1 Overview The H8/3052F has a power-down state that greatly reduces power consumption by halting the CPU, and a module standby function that reduces power consumption by selectively halting onchip modules. The power-down state includes the following three modes: * Sleep mode * Software standby mode * Hardware standby mode The module standby function can halt on-chip supporting modules independently of the powerdown state. The modules that can be halted are the ITU, SCI0, SCI1, DMAC, refresh controller, and A/D converter. Table 20.1 indicates the methods of entering and exiting the power-down modes and module standby mode, and gives the status of the CPU and on-chip supporting modules in each mode. Rev. 2.0, 03/01, page 619 of 822 State CPU Halted Held Active Active Active Active Active Active Active Held output Held * Interrupt * RES * STBY CPU Registers DMAC SCI0 SCI1 A/D I/O Ports Refresh Controller ITU Other Modules RAM Clock Output Exiting Conditions Mode Entering Conditions Clock Sleep mode SLEEP instruction executed while SSBY = 0 in SYSCR Held Halted and held*1 Halted and reset Halted and reset Halted and reset Halted and reset Halted and reset Halted and reset Held High output Held Active Rev. 2.0, 03/01, page 620 of 822 * NMI * IRQ0 to IRQ2 * RES * STBY Undetermined Halted and reset Halted and reset Halted and reset Halted and reset Halted and reset Halted and reset -- Halted*2 Halted*2 Halted*2 Halted*2 Active and and and and reset reset reset reset -- Halted*2 Halted*2 and and reset held*1 Halted and reset Held*3 High impedance High impedance*2 High * STBY impedance * RES * STBY * RES * Clear MSTCR bit to 0*4 Active Software SLEEP standby instruction mode executed while SSBY = 1 in SYSCR Halted Halted Hardware Low input at standby STBY pin mode Halted Halted Module standby Corresponding Active bit set to 1 in MSTCR Table 20.1 Power-Down State and Module Standby Function Notes: 1. 2. 3. 4. RTCNT and bits 7 and 6 of RTMCSR are initialized. Other bits and registers hold their previous states. State in which the corresponding MSTCR bit was set to 1. For details see section 20.2.2, Module Standby Control Register (MSTCR). The RAME bit must be cleared to 0 in SYSCR before the transition from the program execution state to hardware standby mode. When a MSTCR bit is set to 1, the registers of the corresponding on-chip supporting module are initialized. To restart the module, first clear the MSTCR bit to 0, then set up the module registers again. Legend SYSCR: System control register SSBY: Software standby bit MSTCR: Module standby control register 20.2 Register Configuration The H8/3052F has a system control register (SYSCR) that controls the power-down state, and a module standby control register (MSTCR) that controls the module standby function. Table 20.2 summarizes these registers. Table 20.2 Control Register Address* H'FFF2 H'FF5E Name System control register Module standby control register Abbreviation SYSCR MSTCR R/W R/W R/W Initial Value H'0B H'40 Note: * Lower 16 bits of the address. 20.2.1 Bit System Control Register (SYSCR) 7 SSBY 0 R/W 6 STS2 0 R/W 5 STS1 0 R/W 4 STS0 0 R/W 3 UE 1 R/W 2 NMIEG 0 R/W 1 -- 1 -- 0 RAME 1 R/W RAM enable Initial value Read/Write Reserved bit NMI edge select User bit enable Standby timer select 2 to 0 These bits select the waiting time at exit from software standby mode Software standby Enables transition to software standby mode SYSCR is an 8-bit readable/writable register. Bit 7 (SSBY) and bits 6 to 4 (STS2 to STS0) control the power-down state. For information on the other SYSCR bits, see section 3.3, System Control Register (SYSCR). Rev. 2.0, 03/01, page 621 of 822 Bit 7--Software Standby (SSBY): Enables transition to software standby mode. When software standby mode is exited by an external interrupt, this bit remains set to 1 after the return to normal operation. To clear this bit, write 0. Bit 7: SSBY 0 1 Description SLEEP instruction causes transition to sleep mode SLEEP instruction causes transition to software standby mode (Initial value) Bits 6 to 4--Standby Timer Select (STS2 to STS0): These bits select the length of time the CPU and on-chip supporting modules wait for the clock to settle when software standby mode is exited by an external interrupt. If the clock is generated by a crystal resonator, set these bits according to the clock frequency so that the waiting time will be at least 7 ms. See table 20.3. If an external clock is used, Set these bits according to the operating frequency so that the waiting time will be at least 100 s. Bit 6: STS2 0 Bit 5: STS1 0 1 1 0 1 Bit 4: STS0 0 1 0 1 0 1 -- Description Waiting time = 8,192 states Waiting time = 16,384 states Waiting time = 32,768 states Waiting time = 65,536 states Waiting time = 131,072 states Waiting time = 1,024 states Illegal setting (Initial value) Rev. 2.0, 03/01, page 622 of 822 20.2.2 Module Standby Control Register (MSTCR) MSTCR is an 8-bit readable/writable register that controls output of the system clock (). It also controls the module standby function, which places individual on-chip supporting modules in the standby state. Module standby can be designated for the ITU, SCI0, SCI1, DMAC, refresh controller, and A/D converter modules. Bit Initial value Read/Write 7 PSTOP 0 R/W 6 -- 1 -- 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W 0 0 R/W MSTOP5 MSTOP4 MSTOP3 MSTOP2 MSTOP1 MSTOP0 Reserved bit o clock stop Enables or disables output of the system clock Module standby 5 to 0 These bits select modules to be placed in standby MSTCR is initialized to H'40 by a reset and in hardware standby mode. It is not initialized in software standby mode. Bit 7-- Clock Stop (PSTOP): Enables or disables output of the system clock (). Bit 7: PSTOP 0 1 Description System clock output is enabled System clock output is disabled (Initial value) Bit 6--Reserved: Read-only bit, always read as 1. Bit 5--Module Standby 5 (MSTOP5): Selects whether to place the ITU in standby. Bit 5: MSTOP5 0 1 Description ITU operates normally ITU is in standby state (Initial value) Rev. 2.0, 03/01, page 623 of 822 Bit 4--Module Standby 4 (MSTOP4): Selects whether to place SCI0 in standby. Bit 4: MSTOP4 0 1 Description SCI0 operates normally SCI0 is in standby state (Initial value) Bit 3--Module Standby 3 (MSTOP3): Selects whether to place SCI1 in standby. Bit 3: MSTOP3 0 1 Description SCI1 operates normally SCI1 is in standby state (Initial value) Bit 2--Module Standby 2 (MSTOP2): Selects whether to place the DMAC in standby. Bit 2: MSTOP2 0 1 Description DMAC operates normally DMAC is in standby state (Initial value) Bit 1--Module Standby 1 (MSTOP1): Selects whether to place the refresh controller in standby. Bit 1: MSTOP1 0 1 Description Refresh controller operates normally Refresh controller is in standby state (Initial value) Bit 0--Module Standby 0 (MSTOP0): Selects whether to place the A/D converter in standby. Bit 0: MSTOP0 0 1 Description A/D converter operates normally A/D converter is in standby state (Initial value) Rev. 2.0, 03/01, page 624 of 822 20.3 20.3.1 Sleep Mode Transition to Sleep Mode When the SSBY bit is cleared to 0 in SYSCR, execution of the SLEEP instruction causes a transition from the program execution state to sleep mode. Immediately after executing the SLEEP instruction the CPU halts, but the contents of its internal registers are retained. The DMA controller (DMAC), refresh controller, and on-chip supporting modules do not halt in sleep mode. Modules which have been placed in standby by the module standby function, however, remain halted. 20.3.2 Exit from Sleep Mode Sleep mode is exited by an interrupt, or by input at the 5(6 or 67%< pin. Exit by Interrupt: An interrupt terminates sleep mode and causes a transition to the interrupt exception handling state. Sleep mode is not exited by an interrupt source in an on-chip supporting module if the interrupt is disabled in the on-chip supporting module. Sleep mode is not exited by an interrupt other than NMI if the interrupt is masked by the I and UI bits in CCR and IPR. Exit by 5(6 Input: Low input at the 5(6 pin exits from sleep mode to the reset state. Exit by 67%< Input: Low input at the 67%< pin exits from sleep mode to hardware standby mode. Rev. 2.0, 03/01, page 625 of 822 20.4 20.4.1 Software Standby Mode Transition to Software Standby Mode To enter software standby mode, execute the SLEEP instruction while the SSBY bit is set to 1 in SYSCR. In software standby mode, current dissipation is reduced to an extremely low level because the CPU, clock, and on-chip supporting modules all halt. The DMAC and on-chip supporting modules are reset. As long as the specified voltage is supplied, however, CPU register contents and on-chip RAM data are retained. The settings of the I/O ports and refresh controller* are also held. Note: * RTCNT and bits 7 and 6 of RTMCSR are initialized. Other bits and registers hold their previous states. 20.4.2 Exit from Software Standby Mode Software standby mode can be exited by input of an external interrupt at the NMI, ,540, ,541, or ,542 pin, or by input at the 5(6 or 67%< pin. Exit by Interrupt: When an NMI, IRQ0, IRQ1, or IRQ2 interrupt request signal is received, the clock oscillator begins operating. After the oscillator settling time selected by bits STS2 to STS0 in SYSCR, stable clock signals are supplied to the entire chip, software standby mode ends, and interrupt exception handling begins. Software standby mode is not exited if the interrupt enable bits of interrupts IRQ0, IRQ1, and IRQ2 are cleared to 0, or if these interrupts are masked in the CPU. Exit by 5(6 Input: When the 5(6 input goes low, the clock oscillator starts and clock pulses are supplied immediately to the entire chip. The 5(6 signal must be held low long enough for the clock oscillator to stabilize. When 5(6 goes high, the CPU starts reset exception handling. Exit by 67%< Input: Low input at the 67%< pin causes a transition to hardware standby mode. Rev. 2.0, 03/01, page 626 of 822 20.4.3 Selection of Waiting Time for Exit from Software Standby Mode Bits STS2 to STS0 in SYSCR and bits DIV1 and DIV0 in DIVCR should be set as follows. Crystal Resonator: Set STS2 to STS0, DIV1, and DIV0 so that the waiting time (for the clock to stabilize) is at least 7 ms. Table 20.3 indicates the waiting times that are selected by STS2 to STS0, DIV1, and DIV0 settings at various system clock frequencies. External Clock: Set STS2 to STS0, DIV0, and DIV1 so that the waiting time is at least 100 s. Table 20.3 Clock Frequency and Waiting Time for Clock to Settle Waiting DIV1 DIV0 STS2 STS1 STS0 Time 18 MHz 16 MHz 12 MHz 10 MHz 8 MHz 6 MHz 4 MHz 2 MHz 1 MHz Unit 0 0 0 0 0 0 1 1 1 0 1 0 0 0 0 1 1 1 0 0 1 1 0 0 1 0 0 1 1 0 0 1 0 1 0 1 0 1 -- 0 1 0 1 0 1 -- 8192 states 16384 states 32768 states 65536 states 131072 states 1024 states Illegal setting 8192 states 16384 states 32768 states 65536 states 131072 states 1024 states Illegal setting 0.91 1.8 3.6 7.3 14.6 0.11 1.02 2.0 4.1 8.2 16.4 0.13 1.4 2.7 5.5 10.9 21.8 0.17 1.6 3.3 6.6 13.1 26.2 0.20 2.0 4.1 8.2 16.4 32.8 0.26 2.7 5.5 10.9 21.8 43.7 0.34 4.0 8.2 16.4 32.8 65.5 0.51 8.2 16.4 32.8 65.5 16.4 32.8 65.5 131.1 ms 0.46 0.91 1.8 3.6 7.3 0.057 0.51 1.0 2.0 4.1 8.2 0.064 0.65 1.3 2.7 5.5 10.9 0.085 0.8 1.6 3.3 6.6 13.1 0.10 1.0 2.0 4.1 8.2 16.4 0.13 1.3 2.7 5.5 10.9 21.8 0.17 2.0 4.1 8.2 16.4 32.8 0.26 4.1 8.2 16.4 32.8 65.5 0.51 8.2 16.4 32.8 65.5 131.1 1.0 ms 131.1 262.1 1.0 2.0 Rev. 2.0, 03/01, page 627 of 822 Waiting DIV1 DIV0 STS2 STS1 STS0 Time 18 MHz 16 MHz 12 MHz 10 MHz 8 MHz 6 MHz 4 MHz 2 MHz 1 MHz Unit 1 0 0 0 0 0 1 1 1 1 1 0 0 0 0 1 1 1 0 0 1 1 0 0 1 0 0 1 1 0 0 1 0 1 0 1 0 1 -- 0 1 0 1 0 1 -- 8192 states 16384 states 32768 states 65536 states 131072 states 1024 states Illegal setting 8192 states 16384 states 32768 states 65536 states 131072 states 1024 states Illegal setting 3.6 7.3 14.6 29.1 58.3 0.46 4.1 8.2 16.4 32.8 65.5 0.51 5.5 10.9 21.8 43.7 87.4 0.68 6.6 13.1 26.2 52.4 104.9 0.82 8.2 16.4 32.8 65.5 10.9 21.8 43.7 87.4 16.4 32.8 65.5 131.1 32.8 65.5 65.5 131.1 ms 1.8 3.6 7.3 14.6 29.1 0.23 2.0 4.1 8.2 16.4 32.8 0.26 2.7 5.5 10.9 21.8 43.7 0.34 3.3 6.6 13.1 26.2 52.4 0.41 4.1 8.2 16.4 32.8 65.5 0.51 5.5 10.9 21.8 43.7 87.4 0.68 8.2 16.4 32.8 65.5 131.1 1.02 16.4 32.8 65.5 32.8 65.5 131.1 ms 131.1 262.1 262.1 524.3 2.0 4.1 131.1 262.1 262.1 524.3 524.3 1048.6 4.1 8.2 131.1 174.8 262.1 1.0 1.4 2.0 Bold face is recommended setting Rev. 2.0, 03/01, page 628 of 822 20.4.4 Sample Application of Software Standby Mode Figure 20.1 shows an example in which software standby mode is entered at the fall of NMI and exited at the rise of NMI. With the NMI edge select bit (NMIEG) cleared to 0 in SYSCR (selecting the falling edge), an NMI interrupt occurs. Next the NMIEG bit is set to 1 (selecting the rising edge) and the SSBY bit is set to 1; then the SLEEP instruction is executed to enter software standby mode. Software standby mode is exited at the next rising edge of the NMI signal. Clock oscillator NMI NMIEG SSBY NMI interrupt handler NMIEG = 1 SSBY = 1 Software standby mode (powerdown state) Oscillator settling time (tosc2) NMI exception handling SLEEP instruction Figure 20.1 NMI Timing for Software Standby Mode (Example) 20.4.5 Note The I/O ports retain their existing states in software standby mode. If a port is in the high output state, its output current is not reduced. Rev. 2.0, 03/01, page 629 of 822 20.5 20.5.1 Hardware Standby Mode Transition to Hardware Standby Mode Regardless of its current state, the chip enters hardware standby mode whenever the 67%< pin goes low. Hardware standby mode reduces power consumption drastically by halting all functions of the CPU, DMAC, refresh controller, and on-chip supporting modules. All modules are reset except the on-chip RAM. As long as the specified voltage is supplied, on-chip RAM data is retained. I/O ports are placed in the high-impedance state. Clear the RAME bit to 0 in SYSCR before 67%< goes low to retain on-chip RAM data. The inputs at the mode pins (MD2 to MD0) should not be changed during hardware standby mode. 20.5.2 Exit from Hardware Standby Mode Hardware standby mode is exited by inputs at the 67%< and 5(6 pins. While 5(6 is low, when 67%< goes high, the clock oscillator starts running. 5(6 should be held low long enough for the clock oscillator to settle. When 5(6 goes high, reset exception handling begins, followed by a transition to the program execution state. 20.5.3 Timing for Hardware Standby Mode Figure 20.2 shows the timing relationships for hardware standby mode. To enter hardware standby mode, first drive 5(6 low, then drive 67%< low. To exit hardware standby mode, first drive 67%< high, wait for the clock to settle, then bring 5(6 from low to high. Rev. 2.0, 03/01, page 630 of 822 Clock oscillator Oscillator settling time Reset exception handling Figure 20.2 Hardware Standby Mode Timing 20.6 20.6.1 Module Standby Function Module Standby Timing The module standby function can halt several of the on-chip supporting modules (the ITU, SCI0, SCI1, DMAC, refresh controller, and A/D converter) independently of the power-down state. This standby function is controlled by bits MSTOP5 to MSTOP0 in MSTCR. When one of these bits is set to 1, the corresponding on-chip supporting module is placed in standby and halts at the beginning of the next bus cycle after the MSTCR write cycle. 20.6.2 Read/Write in Module Standby When an on-chip supporting module is in module standby, read/write access to its registers is disabled. Read access always results in H'FF data. Write access is ignored. Rev. 2.0, 03/01, page 631 of 822 20.6.3 Usage Notes When using the module standby function, note the following points. DMAC and Refresh Controller: When setting bit MSTOP2 or MSTOP1 to 1 to place the DMAC or refresh controller in module standby, make sure that the DMAC or refresh controller is not currently requesting the bus right. If bit MSTOP2 or MSTOP1 is set to 1 when a bus request is present, operation of the bus arbiter becomes ambiguous and a malfunction may occur. Internal Peripheral Module Interrupt: When MSTCR is set to "1", prevent module interrupt in advance. When an on-chip supporting module is placed in standby by the module standby function, its registers are initialized. Pin States: Pins used by an on-chip supporting module lose their module functions when the module is placed in module standby. What happens after that depends on the particular pin. For details, see section 9, I/O Ports. Pins that change from the input to the output state require special care. For example, if SCI1 is placed in module standby, the receive data pin loses its receive data function and becomes a generic I/O pin. If its data direction bit is set to 1, the pin becomes a data output pin, and its output may collide with external serial data. Data collisions should be prevented by clearing the data direction bit to 0 or taking other appropriate action. Register Resetting: When an on-chip supporting module is halted by the module standby function, all its registers are initialized. To restart the module, after its MSTOP bit is cleared to 0, its registers must be set up again. It is not possible to write to the registers while the MSTOP bit is set to 1. MSTCR Access from DMAC Disabled: To prevent malfunctions, MSTCR can only be accessed from the CPU. It can be read by the DMAC, but it cannot be written by the DMAC. Rev. 2.0, 03/01, page 632 of 822 20.7 System Clock Output Disabling Function Output of the system clock () can be controlled by the PSTOP bit in MSTCR. When the PSTOP bit is set to 1, output of the system clock halts and the pin is placed in the high-impedance state. Figure 20.3 shows the timing of the stopping and starting of system clock output. When the PSTOP bit is cleared to 0, output of the system clock is enabled. Table 20.4 indicates the state of the pin in various operating states. MSTCR write cycle (PSTOP = 1) T1 pin High impedance T2 T3 MSTCR write cycle (PSTOP = 0) T1 T2 T3 Figure 20.3 Starting and Stopping of System Clock Output Table 20.4 Pin State in Various Operating States PSTOP = 0 High impedance Always high System clock output System clock output PSTOP = 1 High impedance High impedance High impedance High impedance Operating State Hardware standby Software standby Sleep mode Normal operation Rev. 2.0, 03/01, page 633 of 822 Rev. 2.0, 03/01, page 634 of 822 Section 21 Electrical Characteristics (Preliminary) 21.1 Absolute Maximum Ratings Table 21.1 lists the absolute maximum ratings. Table 21.1 Absolute Maximum Ratings Item Power supply voltage Programming voltage (FWE) Input voltage (except for port 7) Input voltage (port 7) Reference voltage Analog power supply voltage Analog input voltage Operating temperature Storage temperature HD64F3052 Symbol VCC Vin Vin Vin VREF AVCC VAN Topr Tstg Value 5V operation : -0.3 to +7.0 3V operation : -0.3 to +4.3 -0.3 to VCC + 0.3 -0.3 to VCC + 0.3 -0.3 to AVCC + 0.3 -0.3 to AVCC + 0.3 5V operation : -0.3 to +7.0 3V operation : -0.3 to +4.3 -0.3 to AVCC + 0.3 -20 to +75* -55 to +125 V C C V V V V V Unit V Notes: During 5V operation, connect an external capacitor to the VCL pin. During 3V operation, the VCL pin functions as the VCC pin so the power supply voltage should be applied.Connect an external capacitor between this pin and ground. * For flash memory program/erase operations, the operating temperature range is Ta = 0 to +75C. Caution: Permanent damage to the chip may result if absolute maximum ratings are exceeded. Rev. 2.0, 03/01, page 635 of 822 21.2 21.2.1 Electrical Characteristics DC Characteristics Table 21.2 lists the DC characteristics. Table 21.3 lists the permissible output currents. Table 21.2(1) DC Characteristics Conditions: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, 1 VSS = AVSS = 0 V* , Ta = -20C to +75C Item Schmitt trigger input voltages Input high voltage Port A, P80 to P82, PB0 to PB3 5(6, 67%<, FWE, NMI, MD2 to MD0 EXTAL Port 7 Ports 1, 2, 3, 4, 5, 6, 9, P83, P84, PB4 to PB7 Input low voltage 5(6, 67%<, MD2 to MD0, FWE NMI, EXTAL, ports 1, 2, 3, 4, 5, 6, 7, 9, P83, P84, PB4 to PB7 Output high voltage Output low voltage All output pins All output pins Ports 1, 2, 5, and B VOH VOL VIL Symbol VT - Min 1.0 -- 0.4 VCC - 0.7 Typ -- -- -- -- Max -- VCC x 0.7 -- VCC + 0.3 Unit Test Conditions V V V V VT+ VT+ - VT- VIH VCC x 0.7 2.0 2.0 -- -- -- VCC + 0.3 VCC + 0.3 V V AVCC + 0.3 V -0.3 -- 0.5 V -0.3 -- 0.8 V VCC - 0.5 3.5 -- -- -- -- -- -- -- -- 0.4 1.0 V V V V IOH = -200 A IOH = -1 mA IOL = 1.6 mA IOL = 10 mA Rev. 2.0, 03/01, page 636 of 822 Item Input leakage current 67%<, NMI, 5(6, FWE, MD2 to MD0 Port 7 Three-state leakage current (off state) Ports 1, 2, 3, 4, 5, 6, 8 to B Symbol Min |Iin| -- Typ -- Max 1.0 Unit Test Conditions A Vin = 0.5 to VCC - 0.5 V Vin = 0.5 to AVCC - 0.5 V Vin = 0.5 to VCC - 0.5 V -- |ITSI| -- -- -- 1.0 1.0 A A Input pull-up Ports 2, 4, current and 5 Input FWE capacitance NMI All input pins except NMI -IP Cin 50 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 25 35 23 33 18 25 1.0 -- 35 45 0.5 0.5 0.01 300 60 50 15 48 60 38 50 25 40 10 80 58 70 1.5 1.5 5.0 A pF pF pF mA mA mA mA mA mA A A mA mA mA mA A Vin = 0 V VIN = 0 V f = 1 MHz Ta = 25C f = 18 MHz f = 25 MHz f = 18 MHz f = 25 MHz f = 18 MHz f = 25 MHz Ta 50C 50C < Ta f = 18 MHz f = 25 MHz Current Normal operation ICC 2 dissipation* Sleep mode Module standby 4 mode* Standby mode* Flash programming / erasing Analog power supply current During A/D conversion During A/D and D/A conversion Idle AICC 3 -- -- -- DASTE = 0 Rev. 2.0, 03/01, page 637 of 822 Item Reference current During A/D conversion During A/D and D/A conversion Idle RAM standby voltage Symbol AICC Min -- -- -- Typ 0.4 1.5 0.01 -- Max 0.8 3.0 5.0 -- Unit Test Conditions mA mA A V DASTE = 0 VREF = 5.0 V VRAM 2.0 Notes: 1. If the A/D and D/A converters are not used, do not leave the AVCC, AVSS, and VREF pins open. Connect AVCC and VREF to VCC, and connect AVSS to VSS. 2. Current dissipation values are for VIHmin = VCC - 0.5 V and VILmax = 0.5 V with all output pins unloaded and the on-chip pull-up transistors in the off state. ICC max.(under normal operations) = 3.0(mA) + 0.45(mA/(MHz x V)) x VCC x f ICC max.(when using the sleeve) = 3.0(mA) + 0.35(mA/(MHz x V)) x VCC x f ICC max.(when the sleeve + module are standing by) = 3.0(mA) + 0.26(mA/(MHz x V)) x VCC x f Also,the typ.values for current dissipation are reference values. 3. The values are for VRAM VCC < 4.5 V, VIHmin = VCC x 0.9, and VILmax = 0.3 V. 4. Module standby current values apply in sleep mode with all modules halted. Rev. 2.0, 03/01, page 638 of 822 Table 21.2(2) DC Characteristics Conditions: VCC = 3.0 V to 3.6 V , AVCC = 3.3 V to 5.5V , VREF = 3.0 V to AVCC, 1 VSS = AVSS = 0 V* , Ta = -20C to +75C Item Schmitt Port A, trigger input P80 to P82, PB0 to PB3 voltages Input high voltage 5(6, 67%<, FWE, NMI, MD2 to MD0 EXTAL Port 7 Ports 1, 2, 3, 4, 5, 6, 9, P83, P84, PB4 to PB7 Input low voltage 5(6, 67%<, VIL MD2 to MD0, FWE NMI, EXTAL, ports 1, 2, 3, 4, 5, 6, 7, 9, P83, P84, PB4 to PB7 Output high All output pins voltage VOH Symbol VT VT - + + - Min VCC x 0.2 -- VCC x 0.5 VCC x 0.9 Typ -- -- -- -- Max -- VCC x 0.7 -- VCC + 0.3 Unit Test Conditions V V V V VT - VT VIH VCC x 0.7 VCC x 0.7 VCC x 0.7 -- -- -- VCC + 0.3 VCC + 0.3 V V AVCC + 0.3 V -0.3 -0.3 -- -- VCC x 0.1 VCC x 0.2 V V VCC - 0.5 VCC - 1.0 -- -- -- -- -- -- -- -- -- -- 0.4 1.0 1.0 V V V V A IOH = -200 A IOH = -1 mA IOL = 1.6 mA IOL = 5 mA Vin = 0.5 to VCC - 0.5 V Vin = 0.5 to AVCC - 0.5 V Vin = 0.5 to VCC - 0.5 V Output low All output pins VOL voltage Ports 1, 2, 5, and B Input leakage current 67%<, NMI, 5(6, FWE, MD2 to MD0 Port 7 Three-state Ports 1, 2, 3, leakage 4, 5, 6, 8 to B current (off state) Input pullup current Ports 2, 4, and 5 |ITSI| |Iin| -- -- -- -- 1.0 1.0 A A -IP 10 -- 300 A Vin = 0 V Rev. 2.0, 03/01, page 639 of 822 Item FWE Input capacitance NMI All input pins except NMI Current Normal operation 2 dissipation* Sleep mode Module standby 4 mode* Standby mode* 3 Symbol Min Cin -- -- -- ICC -- -- -- -- -- Flash programming / erasing -- AICC -- -- -- AICC -- -- -- VRAM 2.0 Typ -- -- -- 33 31 23 1.0 -- TBD 0.6 0.6 0.01 0.45 2.0 0.01 -- Max 60 50 15 45 35 27 10 80 TBD 1.5 1.5 5.0 0.8 3.0 5.0 -- Unit Test Conditions pF pF pF mA mA mA A A mA mA mA A mA mA A V DASTE = 0 DASTE = 0 VREF = 5.0 V VIN = 0 V f = 1 MHz Ta = 25C f = 25 MHz f = 25 MHz f = 25 MHz Ta 50C 50C < Ta f = 25 MHz Analog power supply current During A/D conversion During A/D and D/A conversion Idle During A/D conversion During A/D and D/A conversion Idle Reference current RAM standby voltage Notes: 1. If the A/D and D/A converters are not used, do not leave the AVCC, AVSS, and VREF pins open. Connect AVCC and VREF to VCC, and connect AVSS to VSS. 2. Current dissipation values are for VIHmin = VCC - 0.5 V and VILmax = 0.5 V with all output pins unloaded and the on-chip pull-up transistors in the off state. ICC max.(under normal operations) = 3.0(mA) + 0.45(mA/(MHz x V)) x VCC x f ICC max.(when using the sleeve) = 3.0(mA) + 0.35(mA/(MHz x V)) x VCC x f ICC max.(when the sleeve + module are standing by) = 3.0(mA) + 0.26(mA/(MHz x V)) x VCC x f Also,the typ.values for current dissipation are reference values. 3. The values are for VRAM VCC < 4.5 V, VIHmin = VCC x 0.9, and VILmax = 0.3 V. 4. Module standby current values apply in sleep mode with all modules halted. Rev. 2.0, 03/01, page 640 of 822 Table 21.3 Permissible Output Currents Conditions: VCC = 3.0 V to 5.5 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, Ta = -20C to +75C Item Permissible output low current (per pin) Permissible output low current (total) Ports 1, 2, 5, and B Other output pins Total of 28 pins in ports 1, 2, 5, and B Total of all output pins, including the above Permissible output high current (per pin) Permissible output high current (total) All output pins Total of all output pins IOH IOH IOL Symbol IOL Min -- -- -- -- -- -- Typ -- -- -- -- -- -- Max 10 2.0 80 120 2.0 40 Unit mA mA mA mA mA mA Notes: 1. To protect chip reliability, do not exceed the output current values in table 21.3. 2. When driving a darlington pair or LED, always insert a current-limiting resistor in the output line, as shown in figures 21.1 and 21.2. Rev. 2.0, 03/01, page 641 of 822 H8/3052F 2 k Port Darlington pair Figure 21.1 Darlington Pair Drive Circuit (Example) H8/3052F Ports 1, 2, 5, and B 600 LED Figure 21.2 LED Drive Circuit (Example) Rev. 2.0, 03/01, page 642 of 822 21.2.2 AC Characteristics Bus timing parameters are listed in table 21.4. Refresh controller bus timing parameters are listed in table 21.5. Control signal timing parameters are listed in table 21.6. Timing parameters of the on-chip supporting modules are listed in table 21.7. Table 21.4 Bus Timing Condition A: VCC = 3.0 V to 3.6V, AVCC = 3.3 V to 5.5V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C -- Preliminary -- Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item Clock cycle time Clock pulse low width Symbol Min tcyc tCL 40 10 10 -- -- -- 0.5tcyc-20 -- -- -- 1.0tcyc-25 1.5tcyc-25 0.5tcyc-25 1.0tcyc-25 15 0 Max 500 -- -- 10 10 30 -- 25 25 25 -- -- -- -- -- -- Condition B Min 55.5 17 17 -- -- -- 10 -- -- -- 32 62 10 38 15 0 Max 500 -- -- 10 10 25 -- 25 25 25 -- -- -- -- -- -- Condition C Min 40 10 10 -- -- -- 0.5tcyc-20 -- -- -- 1.0tcyc-25 1.5tcyc-25 0.5tcyc-20 1.0tcyc-20 15 0 Max 500 -- -- 10 10 25 -- 25 25 25 -- -- -- -- -- -- Test Unit Conditions ns Figure 21.4, Figure 21.5 Clock pulse high width tCH Clock rise time Clock fall time Address delay time Address hold time Address strobe delay time tCR tCF tAD tAH tASD Write strobe delay time tWSD Strobe delay time tSD Write data strobe pulse tWSW1* width 1 Write data strobe pulse tWSW2* width 2 Address setup time 1 Address setup time 2 Read data setup time Read data hold time tAS1 tAS2 tRDS tRDH Rev. 2.0, 03/01, page 643 of 822 Condition A Item Write data delay time Symbol Min tWDD -- Max 40 Condition B Min -- 10 -10 20 -- -- -- -- 40 25 5 40 -- -- -- Max 55 -- -- -- 50 105 20 80 -- -- -- -- 30 30 40 Min -- Condition C Max 35 Unit ns Test Conditions Write data setup time 1 tWDS1 Write data setup time 2 tWDS2 Write data hold time tWDH Read data access time tACC1* 1 Read data access time tACC2* 2 Read data access time tACC3* 3 Read data access time tACC4* 4 Precharge time Wait setup time Wait hold time tPCH* tWTS tWTH tBACD1 tBACD2 tBZD 1.0tcyc-30 -- -10 -- 0.5tcyc-15 -- -- -- -- -- 1.5tcyc-40 2.5tcyc-40 1.0tcyc-28 2.0tcyc-32 1.0tcyc-30 -- -10 -- 0.5tcyc-15 -- -- -- -- -- 1.5tcyc-40 2.5tcyc-40 1.0tcyc-28 2.0tcyc-32 Figure 21.4, Figure 21.5 1.0tcyc-20 -- 25 5 25 -- -- -- -- -- -- 30 30 40 1.0tcyc-20 -- 25 5 25 -- -- -- -- -- -- 30 30 40 Figure 21.17 Figure 21.6 Bus request setup ime tBRQS Bus acknowledge delay time 1 Bus acknowledge delay time 2 Bus-floating time Note: * At 18 MHz, the times below depend as indicated on the clock cycle time. tACC1 = 1.5 x tcyc - 34 (ns) tWSW1 = 1.0 x tcyc - 24 (ns) tACC2 = 2.5 x tcyc - 34 (ns) tWSW2 = 1.5 x tcyc - 22 (ns) tACC3 = 1.0 x tcyc - 36 (ns) tPCH = 1.0 x tcyc - 21 (ns) tACC4 = 2.0 x tcyc - 31 (ns) Rev. 2.0, 03/01, page 644 of 822 Table 21.5 Refresh Controller Bus Timing Condition A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C -- Preliminary -- Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item 5$6 delay time 1 5$6 delay time 2 5$6 delay time 3 Row address hold time* 5$6 precharge time* Symbol Min tRAD1 tRAD2 tRAD3 tRAH tRP -- -- -- 0.5tcyc-5 Max 25 25 25 -- Condition B Min -- -- -- 15 45 45 40 -- -- -- 15 15 -- Max 30 30 -- -- -- -- -- 85 55 30 -- -- 30 Min -- -- -- 0.5tcyc-5 Condition C Max 18 18 18 -- Test Unit Conditions ns Figure 21.7 to Figure 21.14 1.0tcyc-15 -- 1.0tcyc-15 -- 1.0tcyc-18 -- -- -- -- 15 2.0tcyc-35 1.5tcyc-40 1.0tcyc-30 -- 1.0tcyc-15 -- 1.0tcyc-15 -- 1.0tcyc-18 -- -- -- -- 15 2.0tcyc-35 1.5tcyc-40 1.0tcyc-30 -- &$6 to RAS precharge tCRP time* &$6 pulse width 5$6 access time* Address access time &$6 access time* &$6 setup time* tCAS tRAC tAA tCAC tCSR Write data setup time 3 tWDS3 Read strobe delay time tRSD 0.5tcyc-15 -- -- 25 0.5tcyc-15 -- -- 25 Note: * At 18 MHz, the times below depend as indicated on the clock cycle time. tRAH = 0.5 x tcyc - 17 (ns) tCAC = 1.0 x tcyc - 33 (ns) tRAC = 2.0 x tcyc - 40 (ns) tCSR = 0.5 x tcyc - 17 (ns) tRP = tCRP = 1.0 x tcyc - 18 (ns) Rev. 2.0, 03/01, page 645 of 822 Table 21.6 Control Signal Timing Condition A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C -- Preliminary -- Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item 5(6 setup time 5(6 pulse width Mode programming setup time NMI setup time (NMI, ,545 to ,540) NMI hold time (NMI, ,545 to ,540) Symbol Min tRESS tRESW tMDS tNMIS tNMIH 200 20 200 150 10 200 Max -- -- -- -- -- -- Condition B Min 200 20 200 150 10 200 Max -- -- -- -- -- -- Condition C Min 200 20 200 150 10 200 Max -- -- -- -- -- -- Unit ns tcyc ns ns Figure 21.16 Test Conditions Figure 21.15 Interrupt pulse width tNMIW (NMI,#,545 to ,542 when exiting software standby mode) Clock oscillator settling time at reset (crystal) Clock oscillator settling time in software standby (crystal) tOSC1 20 -- 20 -- 20 -- ms Figure 21.18 tOSC2 7 -- 7 -- 7 -- ns Figure 20.1 Rev. 2.0, 03/01, page 646 of 822 Table 21.7 Timing of On-Chip Supporting Modules Condition A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C -- Preliminary -- Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item DMAC '5(4 setup time '5(4 hold time 7(1' delay time 1 7(1' delay time 2 ITU Timer output delay time Timer input setup time Timer clock input setup time Timer clock Single edge pulse width Both edges SCI Input clock cycle Asynchronous Synchronous Symbol Min tDRQS tDRQH tTED1 tTED2 tTOCD tTICS tTCKS tTCKWH tTCKWL tSCYC tSCYC tSCKr tSCKf tSCKW tTXD tRXS tRXH 20 10 -- -- -- 40 40 1.5 2.5 4 6 -- -- 0.4 -- 100 100 0 -- 50 50 Max -- -- 50 50 100 -- -- -- -- -- -- 1.5 1.5 0.6 100 -- -- -- 100 -- -- Condition B Min 30 10 -- -- -- 50 50 1.5 2.5 4 6 -- -- 0.4 -- 100 100 0 -- 50 50 Max -- -- 50 50 100 -- -- -- -- -- -- 1.5 1.5 0.6 100 -- -- -- 100 -- -- Condition C Min 20 10 -- -- -- 40 40 1.5 2.5 4 6 -- -- 0.4 -- 100 100 0 -- 50 50 Max -- -- 50 50 50 -- -- -- -- -- -- 1.5 1.5 0.6 100 -- -- -- 50 -- -- ns Figure 21.19 tscyc ns Figure 21.23 tcyc Figure 21.22 tcyc Figure 21.21 ns Figure 21.24, Figure 21.25 Figure 21.20 Test Unit Conditions ns Figure 21.16 Input clock rise time Input clock fall time Input clock pulse width Transmit data delay time Receive data setup time (synchronous) Receive data hold time (synchronous) Ports and TPC Clock input Clock output tRXH tPWD tPRS tPRH Output data delay time Input data setup time Input data hold time Rev. 2.0, 03/01, page 647 of 822 5V C = 90 pF: ports 4, 5, 6, 8, A (19 to 0), D (15 to 8), C = 30 pF: ports 9, A, B R L = 2.4 k R H = 12 k C RH Input/output timing measurement levels * Low: 0.8 V * High: 2.0 V RL H8/3052 F-ZTAT output pin Figure 21.3 Output Load Circuit Rev. 2.0, 03/01, page 648 of 822 21.2.3 A/D Conversion Characteristics Table 21.8 lists the A/D conversion characteristics. Table 21.8 A/D Converter Characteristics -- Preliminary -- Condition A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item Resolution Conversion time Analog input capacitance Permissible signal-source impedance Nonlinearity error Offset error Full-scale error Quantization error Absolute accuracy Notes: 1 2 3 4 Min 10 -- -- -- -- -- -- -- -- -- Typ Max 10 -- -- -- -- -- -- -- -- -- 10 134tcyc 20 3 10* Condition B Min Typ Max 10 -- -- -- -- -- -- -- -- -- 10 -- -- -- -- -- -- -- -- -- 10 7.5 20 1 10* Condition C Min Typ Max 10 -- -- -- -- -- -- -- -- -- 10 -- -- -- -- -- -- -- -- -- 10 134tcyc 20 1 10* Unit bits s pF k LSB LSB LSB LSB LSB 5* 4 5* 2 5* 2 7.5 7.5 7.5 0.5 8.0 3.5 3.5 3.5 0.5 4.0 3.5 3.5 3.5 0.5 4.0 The value is for 12 MHz. The value is for > 12 MHz. The value is for 12 MHz and AVCC =4.0V to 5.5V The value is for > 12 MHz and AVCC =3.3V to 4.0V Rev. 2.0, 03/01, page 649 of 822 21.2.4 D/A Conversion Characteristics Table 21.9 lists the D/A conversion characteristics. Table 21.9 D/A Converter Characteristics -- Preliminary -- Condition A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VREF = 3.0 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition B: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 1 MHz to 18 MHz, Ta = -20C to +75C Condition C: VCC = 5.0 V 10%, AVCC = 5.0 V 10%, VREF = 4.5 V to AVCC, VSS = AVSS = 0 V, = 2 MHz to 25 MHz, Ta = -20C to +75C Condition A Item Resolution Absolute accuracy Min Typ Max 8 -- -- 8 -- 8 10 8 -- -- -- Condition B Min Typ Max 8 -- 8 10 8 -- -- -- Condition C Min Typ Max 8 -- 8 10 Unit Bits s LSB LSB 20-pF capacitive load 2-M resistive load 4-M resistive load Test Conditions Conversion time -- 2.0 3.0 -- 2.0 1.0 1.5 -- 1.0 1.5 2.0 -- 1.5 Rev. 2.0, 03/01, page 650 of 822 21.2.5 Flash Memory Characteristics Flash Memory Characteristics Table 21.10 Conditions A: VCC = 3.0 V to 3.6 V, AVCC = 3.3 V to 5.5 V, VSS = AVSS = 0 V, Ta = 0C to +75C (program/erase operating temperature range) Conditions B: VCC = 4.5 V to 5.5 V, AVCC = 4.5 V to 5.5 V, VSS = AVSS = 0 V, Ta = 0C to +75C (program/erase operating temperature range) Condition A,B Item 1, 2, 4 Programming time* * * 1, 3, 5 Erase time* * * Symbol Min tP tE NWEC 1 Typ 10 100 -- 1 50 30 200 10 Max Unit 200 ms/128 bytes Notes -- -- -- 1 50 28 198 8 1200 ms/block 100 -- -- 32 202 12 Times s s s s s Programming time wait Programming time wait Additional programming time wait Reprogramming count Programming Wait time after SWE bit setting* Wait time after PSU bit setting* 1, 4 Wait time after P bit setting* * 1 tsswe tspsu tsp30 tsp200 tsp10 Wait time after P bit clear* 1 tcp 1 5 5 4 2 2 100 -- 1 100 10 10 10 20 2 4 100 12 5 5 4 2 2 100 -- 1 100 10 10 10 20 2 4 100 -- -- -- -- -- -- s s s s s s Wait time after PSU bit clear* tcpsu tspv 1 Wait time after PV bit setting* 1 1 Wait time after H'FF dummy write* Wait time after PV bit clear* 1 tspvr tcpv tcswe N tsswe tsesu tse tce Wait time after SWE bit clear* 1, 4 Maximum programming count* * 1000 Times -- -- 100 -- -- -- -- -- 120 s s ms s s s s s s Times Erase time wait Erase Wait time after SWE bit setting* Wait time after ESU bit setting* 1, 5 Wait time after E bit setting* * 1 1 Wait time after E bit clear* 1 Wait time after ESU bit clear* 1 tcesu tsev 1 Wait time after EV bit setting* 1 1 Wait time after H'FF dummy write* Wait time after EV bit clear* 1, 5 Maximum erase count* * 1 tsevr tcev tcswe N Wait time after SWE bit clear* Rev. 2.0, 03/01, page 651 of 822 Notes: 1. Set the times according to the program/erase algorithms. 2. Programming time per 128 bytes. (Shows the total time the P1 bit or P2 bit in the flash memory control register (FLMCR1 or FLMCR2) is set. It does not include the programming verification time.) 3. Block erase time. (Shows the total time the E1 bit in FLMCR1 or E2 bit in FLMCR2 is set. It does not include the erase verification time.) 4. To specify the maximum programming time value (tP(max)) in the 128-byte programming algorithm, set the max. value (1000) for the maximum programming count (N). The wait time after P bit setting should be changed as follows according to the value of the programming counter (n). Programming counter (n) = 1 to 6: tsp30 = 30 s Programming counter (n) = 7 to 1000: tsp200 = 200 s Programming counter (n) [in additional programming] = 1 to 6: tsp10 = 10 s 5. For the maximum erase time (tE(max)), the following relationship applies between the wait time after E bit setting (tse) and the maximum erase count (N): tE(max) = Wait time after E bit setting (tse) x maximum erase count (N) To set the maximum erase time, the values of tse and N should be set so as to satisfy the above formula. Examples: When tse = 100 [ms], N = 12 When tse = 10 [ms], N = 120 21.3 Operational Timing This section shows timing diagrams. 21.3.1 Bus Timing Bus timing is shown as follows: * Basic bus cycle: two-state access Figure 21.4 shows the timing of the external two-state access cycle. * Basic bus cycle: three-state access Figure 21.5 shows the timing of the external three-state access cycle. * Basic bus cycle: three-state access with one wait state Figure 21.6 shows the timing of the external three-state access cycle with one wait state inserted. Rev. 2.0, 03/01, page 652 of 822 T1 tCYC tCH tCF tAD A23 to A0, 7 to 0 T2 tCL tcyc tCR tPCH tASD tAS1 tPCH tASD tACC3 tSD tAH tACC3 tSD tAH (read) tAS1 tACC1 tRDS tRDH D15 to D0 (read) tASD , (write) tAS1 tWSW1 tWDD D15 to D0 (write) tWDS1 tWDH tSD tAH tPCH Figure 21.4 Basic Bus Cycle: Two-State Access Rev. 2.0, 03/01, page 653 of 822 T1 A23 to A0 T2 T3 tACC4 tACC4 (read) tACC2 D15 to D0 (read) tWSD , (write) D15 to D0 (write) tAS2 tWDS2 tWSW2 tRDS Figure 21.5 Basic Bus Cycle: Three-State Access Rev. 2.0, 03/01, page 654 of 822 T1 A23 to A0 T2 TW T3 (read) D15 to D0 (read) , (write) D15 to D0 (write) tWTS tWTH tWTS tWTH Figure 21.6 Basic Bus Cycle: Three-State Access with One Wait State Rev. 2.0, 03/01, page 655 of 822 21.3.2 Refresh Controller Bus Timing Refresh controller bus timing is shown as follows: * DRAM bus timing Figures 21.7 to 21.12 show the DRAM bus timing in each operating mode. * PSRAM bus timing Figures 21.13 and 21.14 show the pseudo-static RAM bus timing in each operating mode. T1 A9 to A1 tAD tAD T2 T3 tRAD1 3 tRAH tAS1 tASD tRAD3 tRP tCAS tSD tCRP ( ) ( ( ( (read) ( ( (write) ) ), ) tASD tAS1 tRAC tAA tCAC tSD ), ) tWDH tRDS D15 to D0 (read) tWDS3 D15 to D0 (write) tRDH Figure 21.7 DRAM Bus Timing (Read/Write): Three-State Access -- 2:( Mode -- :( Rev. 2.0, 03/01, page 656 of 822 T1 T2 T3 A9 to A1 tASD tSD tCSR 3 tRAD3 ( ) tASD tRAD2 tSD ( ( ( ) ), ) tRAD2 tCSR tRAD3 Figure 21.8 DRAM Bus Timing (Refresh Cycle): Three-State Access -- 2:( Mode -- :( 3 ( ) tCSR tCSR ( ) Figure 21.9 DRAM Bus Timing (Self-Refresh Mode) -- 2#:( Mode -- #:( Rev. 2.0, 03/01, page 657 of 822 T1 tAD tAD T2 T3 A9 to A1 3 ( ) tAS1 tRAD1 tRAH tASD tRAD3 tRP tCAS tSD tCRP ( ( ( ) (read) ), ) tAS1 tRAC tASD tAA tCAC tSD tWDH ( ) (write) tRDS D15 to D0 (read) tWDS3 D15 to D0 (write) tRDH Figure 21.10 DRAM Bus Timing (Read/Write): Three-State Access -- 2&$6 Mode -- &$6 Rev. 2.0, 03/01, page 658 of 822 T1 T2 T3 A9 to A1 tASD tSD tCSR 3 tRAD3 ( ) tASD tRAD2 tSD ( ( ), ) ( ) tRAD2 tCSR tRAD3 Figure 21.11 DRAM Bus Timing (Refresh Cycle): Three-State Access -- 2#&$6 Mode -- #&$6 3 ( ( ( ) ), ) tCSR tCSR Figure 21.12 DRAM Bus Timing (Self-Refresh Mode) -- 2#&$6 Mode -- #&$6 Rev. 2.0, 03/01, page 659 of 822 T1 A23 to A0 tAD T2 T3 tRAD1 3 tRAD3 tRP tAS1 tRSD tRDS tSD (read) tRDH D15 to D0 (read) , (write) tWSD tSD tWDS2 D15 to D0 (write) Figure 21.13 PSRAM Bus Timing (Read/Write): Three-State Access T1 A23 to A0 T2 T3 3, , , tRAD2 tRAD3 Figure 21.14 PSRAM Bus Timing (Refresh Cycle): Three-State Access Rev. 2.0, 03/01, page 660 of 822 21.3.3 Control Signal Timing Control signal timing is shown as follows: * Reset input timing Figure 21.15 shows the reset input timing. * Interrupt input timing Figure 21.16 shows the input timing for NMI and ,545 to ,540. * Bus-release mode timing Figure 21.17 shows the bus-release mode timing. tRESS tRESS tMDS MD2 to MD0 tRESW Figure 21.15 Reset Input Timing Rev. 2.0, 03/01, page 661 of 822  tNMIS NMI tNMIS E tNMIH tNMIH tNMIS L Edge-sensitive : Level-sensitive L NMI j E: i i (i = 0 to 5) tNMIW (j = 0 to 2) Figure 21.16 Interrupt Input Timing tBRQS tBRQS tBACD2 tBACD1 A23 to A0, , , , tBZD tBZD Figure 21.17 Bus-Release Mode Timing Rev. 2.0, 03/01, page 662 of 822 21.3.4 Clock Timing Clock timing is shown as follows: * Oscillator settling timing Figure 21.18 shows the oscillator settling timing. VCC tOSC1 tOSC1 Figure 21.18 Oscillator Settling Timing 21.3.5 TPC and I/O Port Timing Figure 21.19 shows the TPC and I/O port timing. T1 tPRS Port 1 to B (read) T2 T3 tPRH tPWD Port 1 to 6, 8 to B (write) Figure 21.19 TPC and I/O Port Input/Output Timing Rev. 2.0, 03/01, page 663 of 822 21.3.6 ITU Timing ITU timing is shown as follows: * ITU input/output timing Figure 21.20 shows the ITU input/output timing. * ITU external clock input timing Figure 21.21 shows the ITU external clock input timing. tTOCD Output compare*1 tTICS Input capture*2 Notes: 1. TIOCA0 to TIOCA4, TIOCB0 to TIOCB4, TOCXA4, TOCXB4 2. TIOCA0 to TIOCA4, TIOCB0 to TIOCB4 Figure 21.20 ITU Input/Output Timing tTCKS tTCKS TCLKA to TCLKD tTCKWL tTCKWH Figure 21.21 ITU External Clock Input Timing Rev. 2.0, 03/01, page 664 of 822 21.3.7 SCI Input/Output Timing SCI timing is shown as follows: * SCI input clock timing Figure 21.22 shows the SCK input clock timing. * SCI input/output timing (synchronous mode) Figure 21.23 shows the SCI input/output timing in synchronous mode. tSCKW SCK0, SCK1 tScyc tSCKr tSCKf Figure 21.22 SCK Input Clock Timing tScyc SCK0, SCK1 tTXD TxD0, TxD1 (transmit data) RxD0, RxD1 (receive data) tRXS tRXH Figure 21.23 SCI Input/Output Timing in Synchronous Mode Rev. 2.0, 03/01, page 665 of 822 21.3.8 DMAC Timing DMAC timing is shown as follows. * DMAC 7(1' output timing for 2 state access Figure 21.24 shows the DMAC 7(1' output timing for 2 state access. * DMAC 7(1' output timing for 3 state access Figure 21.25 shows the DMAC 7(1' output timing for 3 state access. * DMAC '5(4 input timing Figure 21.26 shows DMAC '5(4 input timing. T1 tTED1 T2 tTED2 Figure 21.24 DMAC 7(1' Output Timing for 2 State Access T1 tTED1 T2 T3 tTED2 Figure 21.25 DMAC 7(1' Output Timing for 3 State Access tDRQS tDRQH Figure 21.26 DMAC '5(4 Input Timing Rev. 2.0, 03/01, page 666 of 822 Appendix A Instruction Set A.1 Instruction List Operand Notation Symbol Rd Rs Rn ERd ERs ERn (EAd) (EAs) PC SP CCR N Z V C disp + - x / ( ), < > Description General destination register General source register General register General destination register (address register or 32-bit register) General source register (address register or 32-bit register) General register (32-bit register) Destination operand Source operand Program counter Stack pointer Condition code register N (negative) flag in CCR Z (zero) flag in CCR V (overflow) flag in CCR C (carry) flag in CCR Displacement Transfer from the operand on the left to the operand on the right, or transition from the state on the left to the state on the right Addition of the operands on both sides Subtraction of the operand on the right from the operand on the left Multiplication of the operands on both sides Division of the operand on the left by the operand on the right Logical AND of the operands on both sides Logical OR of the operands on both sides Exclusive logical OR of the operands on both sides NOT (logical complement) Contents of operand Note: General registers include 8-bit registers (R0H to R7H and R0L to R7L) and 16-bit registers (R0 to R7 and E0 to E7). Rev. 2.0, 03/01, page 667 of 822 Condition Code Notation Symbol Description Changed according to execution result Undetermined (no guaranteed value) Cleared to 0 Set to 1 Not affected by execution of the instruction Varies depending on conditions, described in notes * 0 1 -- Rev. 2.0, 03/01, page 668 of 822 Table A.1 Instruction Set 1. Data transfer instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C MOV.B #xx:8, Rd MOV.B Rs, Rd MOV.B @ERs, Rd MOV.B @(d:16, ERs), Rd MOV.B @(d:24, ERs), Rd MOV.B @ERs+, Rd 2 2 2 4 8 2 ---- ---- ---- ---- ---- ---- B #xx:8 Rd8 B Rs8 Rd8 B @ERs Rd8 B @(d:16, ERs) Rd8 B @(d:24, ERs) Rd8 B @ERs Rd8 ERs32+1 ERs32 B @aa:8 Rd8 B @aa:16 Rd8 B @aa:24 Rd8 B Rs8 @ERd B Rs8 @(d:16, ERd) B Rs8 @(d:24, ERd) B ERd32-1 ERd32 Rs8 @ERd B Rs8 @aa:8 B Rs8 @aa:16 B Rs8 @aa:24 W #xx:16 Rd16 W Rs16 Rd16 W @ERs Rd16 0-- 0-- 0-- 0-- 0-- 0-- 2 2 4 6 10 6 MOV.B @aa:8, Rd MOV.B @aa:16, Rd MOV.B @aa:24, Rd MOV.B Rs, @ERd MOV.B Rs, @(d:16, ERd) MOV.B Rs, @(d:24, ERd) MOV.B Rs, @-ERd 2 4 6 2 4 8 2 ---- ---- ---- ---- ---- ---- ---- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 4 6 8 4 6 10 6 MOV.B Rs, @aa:8 MOV.B Rs, @aa:16 MOV.B Rs, @aa:24 MOV.W #xx:16, Rd MOV.W Rs, Rd MOV.W @ERs, Rd 2 4 6 4 2 2 4 8 2 ---- ---- ---- ---- ---- ---- ---- ---- ---- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 4 6 8 4 2 4 6 10 6 MOV.W @(d:16, ERs), Rd W @(d:16, ERs) Rd16 MOV.W @(d:24, ERs), Rd W @(d:24, ERs) Rd16 MOV.W @ERs+, Rd W @ERs Rd16 ERs32+2 @ERd32 W @aa:16 Rd16 W @aa:24 Rd16 W Rs16 @ERd 2 MOV.W @aa:16, Rd MOV.W @aa:24, Rd MOV.W Rs, @ERd 4 6 ---- ---- ---- 0-- 0-- 0-- 0-- 0-- 6 8 4 6 10 MOV.W Rs, @(d:16, ERd) W Rs16 @(d:16, ERd) MOV.W Rs, @(d:24, ERd) W Rs16 @(d:24, ERd) 4 8 ---- ---- Rev. 2.0, 03/01, page 669 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C MOV.W Rs, @-ERd W ERd32-2 ERd32 Rs16 @ERd W Rs16 @aa:16 W Rs16 @aa:24 L #xx:32 Rd32 L ERs32 ERd32 L @ERs ERd32 L @(d:16, ERs) ERd32 L @(d:24, ERs) ERd32 L @ERs ERd32 ERs32+4 ERs32 L @aa:16 ERd32 L @aa:24 ERd32 L ERs32 @ERd L ERs32 @(d:16, ERd) L ERs32 @(d:24, ERd) L ERd32-4 ERd32 ERs32 @ERd L ERs32 @aa:16 L ERs32 @aa:24 W @SP Rn16 SP+2 SP L @SP ERn32 SP+4 SP W SP-2 SP Rn16 @SP L SP-4 SP ERn32 @SP B Cannot be used in the H8/3052F B Cannot be used in the H8/3052F 4 6 10 6 2 4 6 10 2 ---- 0-- 6 MOV.W Rs, @aa:16 MOV.W Rs, @aa:24 MOV.L #xx:32, Rd MOV.L ERs, ERd MOV.L @ERs, ERd MOV.L @(d:16, ERs), ERd MOV.L @(d:24, ERs), ERd MOV.L @ERs+, ERd 4 6 ---- ---- ---- ---- ---- ---- ---- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 6 8 6 2 8 10 14 10 4 ---- MOV.L @aa:16, ERd MOV.L @aa:24, ERd MOV.L ERs, @ERd MOV.L ERs, @(d:16, ERd) MOV.L ERs, @(d:24, ERd) MOV.L ERs, @-ERd 6 8 ---- ---- ---- ---- ---- 0-- 0-- 0-- 0-- 0-- 0-- 10 12 8 10 14 10 4 ---- MOV.L ERs, @aa:16 MOV.L ERs, @aa:24 POP.W Rn 6 8 ---- ---- 2 ---- 0-- 0-- 0-- 10 12 6 POP.L ERn 4 ---- 0-- 10 PUSH.W Rn 2 ---- 0-- 6 PUSH.L ERn 4 ---- 0-- 10 MOVFPE @aa:16, Rd 4 Cannot be used in the H8/3052F Cannot be used in the H8/3052F MOVTPE Rs, @aa:16 4 Rev. 2.0, 03/01, page 670 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 2. Arithmetic instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C ADD.B #xx:8, Rd ADD.B Rs, Rd ADD.W #xx:16, Rd ADD.W Rs, Rd ADD.L #xx:32, ERd 2 2 4 2 6 -- -- B Rd8+#xx:8 Rd8 B Rd8+Rs8 Rd8 W Rd16+#xx:16 Rd16 W Rd16+Rs16 Rd16 L ERd32+#xx:32 ERd32 L ERd32+ERs32 ERd32 B Rd8+#xx:8 +C Rd8 B Rd8+Rs8 +C Rd8 L ERd32+1 ERd32 L ERd32+2 ERd32 L ERd32+4 ERd32 B Rd8+1 Rd8 W Rd16+1 Rd16 W Rd16+2 Rd16 L ERd32+1 ERd32 L ERd32+2 ERd32 B Rd8 decimal adjust Rd8 B Rd8-Rs8 Rd8 W Rd16-#xx:16 Rd16 W Rd16-Rs16 Rd16 L ERd32-#xx:32 ERd32 L ERd32-ERs32 ERd32 B Rd8-#xx:8-C Rd8 B Rd8-Rs8-C Rd8 L ERd32-1 ERd32 L ERd32-2 ERd32 L ERd32-4 ERd32 B Rd8-1 Rd8 W Rd16-1 Rd16 W Rd16-2 Rd16 2 2 4 2 6 -- (1) -- (1) -- (2) ADD.L ERs, ERd 2 -- (2) 2 ADDX.B #xx:8, Rd ADDX.B Rs, Rd ADDS.L #1, ERd ADDS.L #2, ERd ADDS.L #4, ERd INC.B Rd INC.W #1, Rd INC.W #2, Rd INC.L #1, ERd INC.L #2, ERd DAA Rd 2 2 2 2 2 2 2 2 2 2 2 -- -- (3) (3) 2 2 2 2 2 2 2 2 2 2 2 ------------ ------------ ------------ ---- ---- ---- ---- ---- --* -- -- -- -- -- -- *-- SUB.B Rs, Rd SUB.W #xx:16, Rd SUB.W Rs, Rd SUB.L #xx:32, ERd SUB.L ERs, ERd SUBX.B #xx:8, Rd SUBX.B Rs, Rd SUBS.L #1, ERd SUBS.L #2, ERd SUBS.L #4, ERd DEC.B Rd DEC.W #1, Rd DEC.W #2, Rd 2 4 2 6 2 2 2 2 2 2 2 2 2 2 4 2 6 2 2 2 2 2 2 2 2 2 -- (1) -- (1) -- (2) -- (2) -- -- (3) (3) ------------ ------------ ------------ ---- ---- ---- -- -- -- Rev. 2.0, 03/01, page 671 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C DEC.L #1, ERd DEC.L #2, ERd DAS.Rd 2 2 2 ---- ---- --* L ERd32-1 ERd32 L ERd32-2 ERd32 B Rd8 decimal adjust Rd8 B Rd8 x Rs8 Rd16 (unsigned multiplication) W Rd16 x Rs16 ERd32 (unsigned multiplication) B Rd8 x Rs8 Rd16 (signed multiplication) W Rd16 x Rs16 ERd32 (signed multiplication) B Rd16 / Rs8 Rd16 (RdH: remainder, RdL: quotient) (unsigned division) W ERd32 / Rs16 ERd32 (Ed: remainder, Rd: quotient) (unsigned division) B Rd16 / Rs8 Rd16 (RdH: remainder, RdL: quotient) (signed division) W ERd32 / Rs16 ERd32 (Ed: remainder, Rd: quotient) (signed division) B Rd8-#xx:8 B Rd8-Rs8 W Rd16-#xx:16 W Rd16-Rs16 L ERd32-#xx:32 L ERd32-ERs32 6 4 2 -- -- 2 2 2 *-- MULXU. B Rs, Rd 2 ------------ 14 MULXU. W Rs, ERd 2 ------------ 22 MULXS. B Rs, Rd 4 ---- ---- 16 MULXS. W Rs, ERd 4 ---- ---- 24 DIVXU. B Rs, Rd 2 -- -- (6) (7) -- -- 14 DIVXU. W Rs, ERd 2 -- -- (6) (7) -- -- 22 DIVXS. B Rs, Rd 4 -- -- (8) (7) -- -- 16 DIVXS. W Rs, ERd 4 -- -- (8) (7) -- -- 24 CMP.B #xx:8, Rd CMP.B Rs, Rd CMP.W #xx:16, Rd CMP.W Rs, Rd CMP.L #xx:32, ERd CMP.L ERs, ERd -- 2 -- 2 2 4 2 4 2 -- (1) 2 -- (1) -- (2) 2 -- (2) Rev. 2.0, 03/01, page 672 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C NEG.B Rd NEG.W Rd NEG.L ERd EXTU.W Rd 2 2 2 2 -- -- -- B 0-Rd8 Rd8 W 0-Rd16 Rd16 L 0-ERd32 ERd32 W 0 ( of Rd16) L 0 ( of ERd32) W ( of Rd16) ( of Rd16) L ( of ERd32) ( of ERd32) 2 2 2 2 ---- 0 0-- EXTU.L ERd 2 ---- 0 0-- 2 EXTS.W Rd 2 ---- 0-- 2 EXTS.L ERd 2 ---- 0-- 2 Rev. 2.0, 03/01, page 673 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 3. Logic instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C AND.B #xx:8, Rd AND.B Rs, Rd AND.W #xx:16, Rd AND.W Rs, Rd AND.L #xx:32, ERd AND.L ERs, ERd OR.B #xx:8, Rd OR.B Rs, Rd OR.W #xx:16, Rd OR.W Rs, Rd OR.L #xx:32, ERd OR.L ERs, ERd XOR.B #xx:8, Rd XOR.B Rs, Rd XOR.W #xx:16, Rd XOR.W Rs, Rd XOR.L #xx:32, ERd XOR.L ERs, ERd NOT.B Rd NOT.W Rd NOT.L ERd 2 2 4 2 6 4 2 2 4 2 6 4 2 2 4 2 ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- 4 2 2 2 ---- ---- ---- ---- B Rd8#xx:8 Rd8 B Rd8Rs8 Rd8 W Rd16#xx:16 Rd16 W Rd16Rs16 Rd16 L ERd32#xx:32 ERd32 L ERd32ERs32 ERd32 B Rd8#xx:8 Rd8 B Rd8Rs8 Rd8 W Rd16#xx:16 Rd16 W Rd16Rs16 Rd16 L ERd32#xx:32 ERd32 L ERd32ERs32 ERd32 B Rd8#xx:8 Rd8 B Rd8Rs8 Rd8 W Rd16#xx:16 Rd16 W Rd16Rs16 Rd16 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 0-- 2 2 4 2 6 4 2 2 4 2 6 4 2 2 4 2 6 4 2 2 2 L ERd32#xx:32 ERd32 6 L ERd32ERs32 ERd32 B Rd8 Rd8 W Rd16 Rd16 L Rd32 Rd32 Rev. 2.0, 03/01, page 674 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 4. Shift instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C SHAL.B Rd SHAL.W Rd SHAL.L ERd SHAR.B Rd SHAR.W Rd SHAR.L ERd SHLL.B Rd SHLL.W Rd SHLL.L ERd SHLR.B Rd SHLR.W Rd SHLR.L ERd ROTXL.B Rd ROTXL.W Rd ROTXL.L ERd ROTXR.B Rd ROTXR.W Rd ROTXR.L ERd ROTL.B Rd ROTL.W Rd ROTL.L ERd ROTR.B Rd ROTR.W Rd ROTR.L ERd B W L B W L B W L B W L B W L B W L B W L B W L C MSB LSB C MSB C MSB 0 MSB C MSB LSB C MSB C MSB LSB LSB LSB LSB LSB 0 2 2 2 2 2 2 2 ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 2 2 2 C 2 2 2 2 2 2 2 2 2 2 2 2 C MSB LSB 2 2 Rev. 2.0, 03/01, page 675 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 5. Bit manipulation instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C BSET #xx:3, Rd BSET #xx:3, @ERd BSET #xx:3, @aa:8 BSET Rn, Rd BSET Rn, @ERd BSET Rn, @aa:8 BCLR #xx:3, Rd BCLR #xx:3, @ERd BCLR #xx:3, @aa:8 BCLR Rn, Rd BCLR Rn, @ERd BCLR Rn, @aa:8 BNOT #xx:3, Rd B (#xx:3 of Rd8) 1 B (#xx:3 of @ERd) 1 B (#xx:3 of @aa:8) 1 B (Rn8 of Rd8) 1 B (Rn8 of @ERd) 1 B (Rn8 of @aa:8) 1 B (#xx:3 of Rd8) 0 B (#xx:3 of @ERd) 0 B (#xx:3 of @aa:8) 0 B (Rn8 of Rd8) 0 B (Rn8 of @ERd) 0 B (Rn8 of @aa:8) 0 B (#xx:3 of Rd8) (#xx:3 of Rd8) B (#xx:3 of @ERd) (#xx:3 of @ERd) B (#xx:3 of @aa:8) (#xx:3 of @aa:8) B (Rn8 of Rd8) (Rn8 of Rd8) B (Rn8 of @ERd) (Rn8 of @ERd) B (Rn8 of @aa:8) (Rn8 of @aa:8) B (#xx:3 of Rd8) Z B (#xx:3 of @ERd) Z B (#xx:3 of @aa:8) Z B (Rn8 of @Rd8) Z B (Rn8 of @ERd) Z B (Rn8 of @aa:8) Z B (#xx:3 of Rd8) C 2 4 4 2 4 4 2 4 4 2 4 4 2 ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ 2 8 8 2 8 8 2 8 8 2 8 8 2 BNOT #xx:3, @ERd 4 ------------ 8 BNOT #xx:3, @aa:8 4 ------------ 8 BNOT Rn, Rd 2 ------------ 2 BNOT Rn, @ERd 4 ------------ 8 BNOT Rn, @aa:8 4 ------------ 8 BTST #xx:3, Rd BTST #xx:3, @ERd BTST #xx:3, @aa:8 BTST Rn, Rd BTST Rn, @ERd BTST Rn, @aa:8 BLD #xx:3, Rd 2 4 4 2 4 4 2 ------ ------ ------ ------ ------ ------ ---- ---- ---- ---- ---- ---- 2 6 6 2 6 6 2 ---------- Rev. 2.0, 03/01, page 676 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C BLD #xx:3, @ERd BLD #xx:3, @aa:8 BILD #xx:3, Rd BILD #xx:3, @ERd BILD #xx:3, @aa:8 BST #xx:3, Rd BST #xx:3, @ERd BST #xx:3, @aa:8 BIST #xx:3, Rd BIST #xx:3, @ERd BIST #xx:3, @aa:8 BAND #xx:3, Rd BAND #xx:3, @ERd BAND #xx:3, @aa:8 BIAND #xx:3, Rd BIAND #xx:3, @ERd BIAND #xx:3, @aa:8 BOR #xx:3, Rd BOR #xx:3, @ERd BOR #xx:3, @aa:8 BIOR #xx:3, Rd BIOR #xx:3, @ERd BIOR #xx:3, @aa:8 BXOR #xx:3, Rd BXOR #xx:3, @ERd BXOR #xx:3, @aa:8 BIXOR #xx:3, Rd BIXOR #xx:3, @ERd BIXOR #xx:3, @aa:8 4 4 2 4 4 2 4 4 2 4 4 2 4 4 2 4 4 2 4 4 2 4 4 2 4 4 2 4 4 ---------- ---------- ---------- ---------- ---------- B (#xx:3 of @ERd) C B (#xx:3 of @aa:8) C B (#xx:3 of Rd8) C B (#xx:3 of @ERd) C B (#xx:3 of @aa:8) C B C (#xx:3 of Rd8) B C (#xx:3 of @ERd24) B C (#xx:3 of @aa:8) B C (#xx:3 of Rd8) B C (#xx:3 of @ERd24) B C (#xx:3 of @aa:8) B C(#xx:3 of Rd8) C B C(#xx:3 of @ERd24) C B C(#xx:3 of @aa:8) C B C (#xx:3 of Rd8) C B C (#xx:3 of @ERd24) C B C (#xx:3 of @aa:8) C B C(#xx:3 of Rd8) C B C(#xx:3 of @ERd24) C B C(#xx:3 of @aa:8) C B C (#xx:3 of Rd8) C B C (#xx:3 of @ERd24) C B C (#xx:3 of @aa:8) C B C(#xx:3 of Rd8) C B C(#xx:3 of @ERd24) C B C(#xx:3 of @aa:8) C B C (#xx:3 of Rd8) C B C (#xx:3 of @ERd24) C B C (#xx:3 of @aa:8) C 6 6 2 6 6 2 8 8 2 8 8 2 6 6 2 6 6 2 6 6 2 6 6 2 6 6 2 6 6 ------------ ------------ ------------ ------------ ------------ ------------ ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- Rev. 2.0, 03/01, page 677 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 6. Branching instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) Branch Condition I H N Z V C BRA d:8 (BT d:8) BRA d:16 (BT d:16) BRN d:8 (BF d:8) BRN d:16 (BF d:16) BHI d:8 BHI d:16 BLS d:8 BLS d:16 BCC d:8 (BHS d:8) BCC d:16 (BHS d:16) BCS d:8 (BLO d:8) BCS d:16 (BLO d:16) BNE d:8 BNE d:16 BEQ d:8 BEQ d:16 BVC d:8 BVC d:16 BVS d:8 BVS d:16 BPL d:8 BPL d:16 BMI d:8 BMI d:16 BGE d:8 BGE d:16 BLT d:8 BLT d:16 BGT d:8 BGT d:16 BLE d:8 BLE d:16 -- If condition Always -- is true then PC PC+d Never -- else next; -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Z (NV) = 1 Z (NV) = 0 NV = 1 NV = 0 N=1 N=0 V=1 V=0 Z=1 Z=0 C=1 C=0 CZ=1 CZ=0 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 2 4 ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ ------------ 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 4 6 Rev. 2.0, 03/01, page 678 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C JMP @ERn JMP @aa:24 JMP @@aa:8 BSR d:8 -- PC ERn -- PC aa:24 -- PC @aa:8 -- PC @-SP PC PC+d:8 -- PC @-SP PC PC+d:16 -- PC @-SP PC @ERn -- PC @-SP PC @aa:24 -- PC @-SP PC @aa:8 -- PC @SP+ 2 4 2 2 ------------ ------------ ------------ ------------ 8 6 4 6 10 8 BSR d:16 4 ------------ 8 10 JSR @ERn 2 ------------ 6 JSR @aa:24 4 ------------ 8 10 JSR @@aa:8 2 ------------ 8 12 RTS 2 ------------ 8 10 Rev. 2.0, 03/01, page 679 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 8 7. System control instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C TRAPA #x:2 -- PC @-SP CCR @-SP PC -- CCR @SP+ PC @SP+ -- Transition to powerdown state B #xx:8 CCR B Rs8 CCR W @ERs CCR W @(d:16, ERs) CCR W @(d:24, ERs) CCR W @ERs CCR ERs32+2 ERs32 W @aa:16 CCR W @aa:24 CCR B CCR Rd8 W CCR @ERd W CCR @(d:16, ERd) W CCR @(d:24, ERd) W ERd32-2 ERd32 CCR @ERd W CCR @aa:16 W CCR @aa:24 B CCR#xx:8 CCR B CCR#xx:8 CCR B CCR#xx:8 CCR -- PC PC+2 2 2 2 2 4 6 10 4 2 2 4 6 10 4 2 1 -- -- -- -- -- 14 16 RTE 10 SLEEP ------------ 2 LDC #xx:8, CCR LDC Rs, CCR LDC @ERs, CCR LDC @(d:16, ERs), CCR LDC @(d:24, ERs), CCR LDC @ERs+, CCR 2 2 6 8 12 8 LDC @aa:16, CCR LDC @aa:24, CCR STC CCR, Rd STC CCR, @ERd STC CCR, @(d:16, ERd) STC CCR, @(d:24, ERd) STC CCR, @-ERd 6 8 8 10 2 6 8 12 8 ------------ ------------ ------------ ------------ ------------ STC CCR, @aa:16 STC CCR, @aa:24 ANDC #xx:8, CCR ORC #xx:8, CCR XORC #xx:8, CCR NOP 6 8 ------------ ------------ 8 10 2 2 2 2 2 ------------ Rev. 2.0, 03/01, page 680 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- 8. Block transfer instructions Addressing Mode and Instruction Length (bytes) @-ERn/@ERn+ Operand Size Condition Code No. of States*1 @(d, ERn) I H N Z V C EEPMOV. B -- if R4L 0 then repeat @R5 @R6 R5+1 R5 R6+1 R6 R4L-1 R4L until R4L=0 else next -- if R4 0 then repeat @R5 @R6 R5+1 R5 R6+1 R6 R4-1 R4 until R4=0 else next 4 -- -- -- -- -- -- 8+ 4n*2 EEPMOV. W 4 -- -- -- -- -- -- 8+ 4n*2 Notes: 1. The number of states is the number of states required for execution when the instruction and its operands are located in on-chip memory. For other cases see section A.3, Number of States Required for Execution. 2. n is the value set in register R4L or R4. (1) Set to 1 when a carry or borrow occurs at bit 11; otherwise cleared to 0. (2) Set to 1 when a carry or borrow occurs at bit 27; otherwise cleared to 0. (3) Retains its previous value when the result is zero; otherwise cleared to 0. (4) Set to 1 when the adjustment produces a carry; otherwise retains its previous value. (5) The number of states required for execution of an instruction that transfers data in synchronization with the E clock is variable. (6) Set to 1 when the divisor is negative; otherwise cleared to 0. (7) Set to 1 when the divisor is zero; otherwise cleared to 0. (8) Set to 1 when the quotient is negative; otherwise cleared to 0. Rev. 2.0, 03/01, page 681 of 822 Advanced Mnemonic Operation @ERn @(d, PC) Normal @@aa @aa #xx Rn -- A.2 Table A.2 Instruction code: Instruction when most significant bit of BH is 1. 4 ORC ADD SUB Table A-2 Table A-2 (2) (2) CMP MOV OR.B XOR.B AND.B Table A-2 (2) XORC ANDC LDC Table A-2 Table A-2 (2) (2) ADDX SUBX 5 6 7 8 9 A B C D E F Table A-2 (2) Table A-2 (2) 1st byte 2nd byte AH AL BH BL Instruction when most significant bit of BH is 0. 3 LDC AL AH 0 1 2 0 NOP Table A-2 (2) STC 1 Table A-2 Table A-2 Table A-2 Table A-2 (2) (2) (2) (2) Rev. 2.0, 03/01, page 682 of 822 MOV.B 2 Operation Code Map Operation Code Map 3 BLS BVS JMP MOV MOV BIOR ADD ADDX CMP SUBX OR XOR AND MOV BIXOR BIAND BILD Table A-2 Table A-2 EEPMOV (2) (2) Table A-2 (3) DIVXU BST OR BTST BOR BXOR BAND BIST BLD XOR AND RTS BSR RTE TRAPA Table A-2 (2) BCC BCS BNE BEQ BVC BPL BMI BGE BSR BLT BGT JSR BLE 4 BRA BRN BHI 5 MULXU DIVXU MULXU 6 BSET BNOT BCLR 7 8 9 A B C D E F Table A.2 Instruction code: 1st byte 2nd byte AH AL BH BL 2 LDC/STC SLEEP ADD INC ADDS MOV SHLL SHAL SHAR ROTL ROTR EXTU EXTU NEG SHLR ROTXL ROTXR NOT SHAL SHAR ROTL ROTR NEG SUB DEC DEC SUB CMP BHI BLS SUB SUB OR OR CMP CMP BCC BCS XOR XOR BNE AND AND BEQ BVC BVS BPL BMI BGE BLT BGT BLE DEC DEC EXTS EXTS INC INC INC 3 4 5 6 7 8 9 A B C D E F Table A-2 (3) BH AH AL 0 1 01 MOV Table A-2 Table A-2 (3) (3) 0A INC Operation Code Map 0B ADDS 0F DAA 10 SHLL 11 SHLR 12 ROTXL 13 ROTXR 17 NOT 1A DEC 1B SUBS 1F DAS 58 BRA BRN 79 MOV ADD Rev. 2.0, 03/01, page 683 of 822 7A MOV ADD Table A.2 Instruction code: 1st byte 2nd byte 3rd byte 4th byte AH AL BH BL CH CL DH DL Instruction when most significant bit of DH is 0. Instruction when most significant bit of DH is 1. CL 2 3 4 5 6 7 8 9 A B C D E F AH ALBH BLCH LDC STC STC MULXS DIVXS OR BTST BOR BTST BIOR BCLR BIST BCLR BTST BOR BTST BIOR BCLR BIST BCLR BIXOR BIAND BILD BST BXOR BAND BLD BIXOR BIAND BILD BST BXOR BAND BLD XOR AND LDC 0 1 Rev. 2.0, 03/01, page 684 of 822 LDC STC LDC STC 01406 Operation Code Map 01C05 MULXS 01D05 DIVXS 01F06 7Cr06 * 1 7Cr07 * 1 7Dr06 * 1 BSET BNOT 7Dr07 * 1 BSET BNOT 7Eaa6 * 2 7Eaa7 * 2 7Faa6 * 2 BSET BNOT 7Faa7 * 2 BSET BNOT Notes: 1. r is the register designation field. 2. aa is the absolute address field. A.3 Number of States Required for Execution The tables in this section can be used to calculate the number of states required for instruction execution by the H8/300H CPU. Table A.4 indicates the number of instruction fetch, data read/write, and other cycles occurring in each instruction. Table A.3 indicates the number of states required per cycle according to the bus size. The number of states required for execution of an instruction can be calculated from these two tables as follows: Number of states = I x SI + J x SJ + K x SK + L x SL + M x SM + N x SN Examples of Calculation of Number of States Required for Execution Examples: Advanced mode, stack located in external address space, on-chip supporting modules accessed with 8-bit bus width, external devices accessed in three states with one wait state and 16-bit bus width. BSET #0, @FFFFC7:8 From table A.4, I = L = 2 and J = K = M = N = 0 From table A.3, SI = 4 and SL = 3 Number of states = 2 x 4 + 2 x 3 = 14 JSR @@30 From table A.4, I = J = K = 2 and L = M = N = 0 From table A.3, SI = SJ = SK = 4 Number of states = 2 x 4 + 2 x 4 + 2 x 4 = 24 Rev. 2.0, 03/01, page 685 of 822 Table A.3 Number of States per Cycle Access Conditions On-Chip Supporting Module External Device 8-Bit Bus 2-State Access 4 3-State Access 6 + 2m 16-Bit Bus 2-State Access 2 3-State Access 3+m Cycle Instruction fetch Branch address read Stack operation Byte data access Word data access Internal operation SI SJ SK SL SM SN On-Chip Memory 2 8-Bit Bus 6 16-Bit Bus 3 3 6 1 1 1 2 4 1 3+m 6 + 2m 1 1 1 Legend m: Number of wait states inserted into external device access Rev. 2.0, 03/01, page 686 of 822 Table A.4 Number of Cycles per Instruction Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 1 2 1 3 1 1 1 1 1 1 2 1 3 2 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 1 Instruction Mnemonic ADD ADD.B #xx:8, Rd ADD.B Rs, Rd ADD.W #xx:16, Rd ADD.W Rs, Rd ADD.L #xx:32, ERd ADD.L ERs, ERd ADDS ADDX ADDS #1/2/4, ERd ADDX #xx:8, Rd ADDX Rs, Rd AND AND.B #xx:8, Rd AND.B Rs, Rd AND.W #xx:16, Rd AND.W Rs, Rd AND.L #xx:32, ERd AND.L ERs, ERd ANDC BAND ANDC #xx:8, CCR BAND #xx:3, Rd BAND #xx:3, @ERd BAND #xx:3, @aa:8 Bcc BRA d:8 (BT d:8) BRN d:8 (BF d:8) BHI d:8 BLS d:8 BCC d:8 (BHS d:8) BCS d:8 (BLO d:8) BNE d:8 BEQ d:8 BVC d:8 BVS d:8 BPL d:8 BMI d:8 BGE d:8 BLT d:8 BGT d:8 BLE d:8 Rev. 2.0, 03/01, page 687 of 822 Instruction Mnemonic Bcc BRA d:16 (BT d:16) BRN d:16 (BF d:16) BHI d:16 BLS d:16 BCC d:16 (BHS d:16) BCS d:16 (BLO d:16) BNE d:16 BEQ d:16 BVC d:16 BVS d:16 BPL d:16 BMI d:16 BGE d:16 BLT d:16 BGT d:16 BLE d:16 BCLR BCLR #xx:3, Rd BCLR #xx:3, @ERd BCLR #xx:3, @aa:8 BCLR Rn, Rd BCLR Rn, @ERd BCLR Rn, @aa:8 BIAND BIAND #xx:3, Rd BIAND #xx:3, @ERd BIAND #xx:3, @aa:8 BILD BILD #xx:3, Rd BILD #xx:3, @ERd BILD #xx:3, @aa:8 BIOR BIOR #xx:8, Rd BIOR #xx:8, @ERd BIOR #xx:8, @aa:8 BIST BIST #xx:3, Rd BIST #xx:3, @ERd BIST #xx:3, @aa:8 Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 2 2 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 Rev. 2.0, 03/01, page 688 of 822 Instruction Mnemonic BIXOR BIXOR #xx:3, Rd BIXOR #xx:3, @ERd BIXOR #xx:3, @aa:8 BLD BLD #xx:3, Rd BLD #xx:3, @ERd BLD #xx:3, @aa:8 BNOT BNOT #xx:3, Rd BNOT #xx:3, @ERd BNOT #xx:3, @aa:8 BNOT Rn, Rd BNOT Rn, @ERd BNOT Rn, @aa:8 BOR BOR #xx:3, Rd BOR #xx:3, @ERd BOR #xx:3, @aa:8 BSET BSET #xx:3, Rd BSET #xx:3, @ERd BSET #xx:3, @aa:8 BSET Rn, Rd BSET Rn, @ERd BSET Rn, @aa:8 BSR BSR d:8 Normal* 1 Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 2 2 2 2 1 2 2 1 2 2 1 2 2 1 1 1 1 2 2 1 2 1 2 2 2 2 2 2 2 1 1 2 2 2 2 1 1 1 1 Advanced BSR d:16 1 Normal* Advanced BST BST #xx:3, Rd BST #xx:3, @ERd BST #xx:3, @aa:8 BTST BTST #xx:3, Rd BTST #xx:3, @ERd BTST #xx:3, @aa:8 BTST Rn, Rd BTST Rn, @ERd BTST Rn, @aa:8 Rev. 2.0, 03/01, page 689 of 822 Instruction Mnemonic BXOR BXOR #xx:3, Rd BXOR #xx:3, @ERd BXOR #xx:3, @aa:8 CMP CMP.B #xx:8, Rd CMP.B Rs, Rd CMP.W #xx:16, Rd CMP.W Rs, Rd CMP.L #xx:32, ERd CMP.L ERs, ERd DAA DAS DEC DAA Rd DAS Rd DEC.B Rd DEC.W #1/2, Rd DEC.L #1/2, ERd DIVXS DIVXS.B Rs, Rd DIVXS.W Rs, ERd DIVXU DIVXU.B Rs, Rd DIVXU.W Rs, ERd EEPMOV EEPMOV.B EEPMOV.W EXTS EXTS.W Rd EXTS.L ERd EXTU EXTU.W Rd EXTU.L ERd INC INC.B Rd INC.W #1/2, Rd INC.L #1/2, ERd JMP JMP @ERn JMP @aa:24 1 JMP @@aa:8 Normal* Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 2 2 1 1 2 1 3 1 1 1 1 1 1 2 2 1 1 2 2 1 1 1 1 1 1 1 2 2 2 2 1 2 2 2 2 2 2n + 2* 1 1 12 20 12 20 2n + 2* 2 Advanced Rev. 2.0, 03/01, page 690 of 822 Instruction Mnemonic JSR JSR @ERn Normal* 1 Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 2 2 2 2 2 2 1 1 2 3 5 2 3 4 1 1 1 2 4 1 1 2 3 1 2 4 1 1 2 3 2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 2 2 1 1 1 1 1 1 2 1 2 1 2 1 2 1 2 2 2 Advanced JSR @aa:24 1 Normal* Advanced 1 JSR @@aa:8 Normal* Advanced LDC LDC #xx:8, CCR LDC Rs, CCR LDC @ERs, CCR LDC @(d:16, ERs), CCR LDC @(d:24, ERs), CCR LDC @ERs+, CCR LDC @aa:16, CCR LDC @aa:24, CCR MOV MOV.B #xx:8, Rd MOV.B Rs, Rd MOV.B @ERs, Rd MOV.B @(d:16, ERs), Rd MOV.B @(d:24, ERs), Rd MOV.B @ERs+, Rd MOV.B @aa:8, Rd MOV.B @aa:16, Rd MOV.B @aa:24, Rd MOV.B Rs, @ERd MOV.B Rs, @(d:16, ERd) MOV.B Rs, @(d:24, ERd) MOV.B Rs, @-ERd MOV.B Rs, @aa:8 MOV.B Rs, @aa:16 MOV.B Rs, @aa:24 MOV.W #xx:16, Rd MOV.W Rs, Rd MOV.W @ERs, Rd MOV.W @(d:16, ERs), Rd 2 Rev. 2.0, 03/01, page 691 of 822 Instruction Mnemonic MOV Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 1 1 1 1 1 1 1 1 1 2 2 MOV.W @(d:24, ERs), Rd 4 MOV.W @ERs+, Rd MOV.W @aa:16, Rd MOV.W @aa:24, Rd MOV.W Rs, @ERd 1 2 3 1 MOV.W Rs, @(d:16, ERd) 2 MOV.W Rs, @(d:24, ERd) 4 MOV.W Rs, @-ERd MOV.W Rs, @aa:16 MOV.W Rs, @aa:24 MOV.L #xx:32, ERd MOV.L ERs, ERd MOV.L @ERs, ERd 1 2 3 3 1 2 2 2 2 2 2 2 2 2 2 2 2 2 1 1 12 20 12 20 2 2 MOV.L @(d:16, ERs), ERd 3 MOV.L @(d:24, ERs), ERd 5 MOV.L @ERs+, ERd MOV.L @aa:16, ERd MOV.L @aa:24, ERd MOV.L ERs, @ERd 2 3 4 2 MOV.L ERs, @(d:16, ERd) 3 MOV.L ERs, @(d:24, ERd) 5 MOV.L ERs, @-ERd MOV.L ERs, @aa:16 MOV.L ERs, @aa:24 MOVFPE MOVTPE MULXS MOVFPE @aa:16, Rd* 1 2 3 4 2 2 2 2 1 1 1 1 1 1 1 MOVTPE Rs, @aa:16* MULXS.B Rs, Rd MULXS.W Rs, ERd MULXU MULXU.B Rs, Rd MULXU.W Rs, ERd NEG NEG.B Rd NEG.W Rd NEG.L ERd NOP NOP Rev. 2.0, 03/01, page 692 of 822 Instruction Mnemonic NOT NOT.B Rd NOT.W Rd NOT.L ERd OR OR.B #xx:8, Rd OR.B Rs, Rd OR.W #xx:16, Rd OR.W Rs, Rd OR.L #xx:32, ERd OR.L ERs, ERd ORC POP ORC #xx:8, CCR POP.W Rn POP.L ERn PUSH PUSH.W Rn PUSH.L ERn ROTL ROTL.B Rd ROTL.W Rd ROTL.L ERd ROTR ROTR.B Rd ROTR.W Rd ROTR.L ERd ROTXL ROTXL.B Rd ROTXL.W Rd ROTXL.L ERd ROTXR ROTXR.B Rd ROTXR.W Rd ROTXR.L ERd RTE RTS RTE RTS Normal* 1 Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 1 1 1 1 2 1 3 2 1 1 2 1 2 1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 1 1 1 1 1 1 2 1 2 2 2 2 1 2 1 2 2 2 2 2 Advanced SHAL SHAL.B Rd SHAL.W Rd SHAL.L ERd SHAR SHAR.B Rd SHAR.W Rd SHAR.L ERd Rev. 2.0, 03/01, page 693 of 822 Instruction Mnemonic SHLL SHLL.B Rd SHLL.W Rd SHLL.L ERd SHLR SHLR.B Rd SHLR.W Rd SHLR.L ERd SLEEP STC SLEEP STC CCR, Rd STC CCR, @ERd STC CCR, @(d:16, ERd) STC CCR, @(d:24, ERd) STC CCR, @-ERd STC CCR, @aa:16 STC CCR, @aa:24 SUB SUB.B Rs, Rd SUB.W #xx:16, Rd SUB.W Rs, Rd SUB.L #xx:32, ERd SUB.L ERs, ERd SUBS SUBX SUBS #1/2/4, ERd SUBX #xx:8, Rd SUBX Rs, Rd TRAPA 1 TRAPA #x:2 Normal* Instruction Branch Stack Byte Data Word Data Internal Fetch Addr. Read Operation Access Access Operation I J K L M N 1 1 1 1 1 1 1 1 2 3 5 2 3 4 1 2 1 3 1 1 1 1 2 2 1 1 2 1 3 2 1 1 2 2 2 4 4 1 1 1 1 1 1 2 Advanced XOR XOR.B #xx:8, Rd XOR.B Rs, Rd XOR.W #xx:16, Rd XOR.W Rs, Rd XOR.L #xx:32, ERd XOR.L ERs, ERd XORC XORC #xx:8, CCR Notes: 1. Not available in the H83052F. 2. n is the value set in register R4L or R4. The source and destination are accessed n + 1 times each. Rev. 2.0, 03/01, page 694 of 822 Appendix B Internal I/O Register B.1 Addresses Data Bus Width Bit 7 Bit Names Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Module Name Address Register (low) Name H'1C H'1D H'1E H'1F H'20 H'21 H'22 H'23 H'24 H'25 H'26 H'27 MAR0AR MAR0AE MAR0AH MAR0AL ETCR0AH ETCR0AL IOAR0A DTCR0A Reserved area (access prohibited) 8 8 8 8 8 8 8 8 DTE DTSZ DTID RPE DTIE DTS2 DTS1 DTS0 DMAC channel 0A Short address mode Full address mode DMAC channel 0B DTE DTSZ SAID SAIDE DTIE DTS2A DTS1A DTS0A H'28 H'29 H'2A H'2B H'2C H'2D H'2E H'2F MAR0BR MAR0BE MAR0BH MAR0BL ETCR0BH ETCR0BL IOAR0B DTCR0B 8 8 8 8 8 8 8 8 DTE DTSZ DTID RPE DTIE DTS2 DTS1 DTS0 Short address mode Full address mode DTME -- DAID DAIDE TMS DTS2B DTS1B DTS0B Rev. 2.0, 03/01, page 695 of 822 Address Register (low) Name H'30 H'31 H'32 H'33 H'34 H'35 H'36 H'37 MAR1AR MAR1AE MAR1AH MAR1AL ETCR1AH ETCR1AL IOAR1A DTCR1A Data Bus Width Bit 7 8 8 8 8 8 8 8 8 DTE Bit Names Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Module Name DMAC channel 1A DTSZ DTID RPE DTIE DTS2 DTS1 DTS0 Short address mode Full address mode DMAC channel 1B DTE DTSZ SAID SAIDE DTIE DTS2A DTS1A DTS0A H'38 H'39 H'3A H'3B H'3C H'3D H'3E H'3F MAR1BR MAR1BE MAR1BH MAR1BL ETCR1BH ETCR1BL IOAR1B DTCR1B 8 8 8 8 8 8 8 8 DTE DTSZ DTID RPE DTIE DTS2 DTS1 DTS0 Short address mode Full address mode Flash memory DTME -- DAID DAIDE TMS DTS2B DTS1B DTS0B H'40 H'41 H'42 H'43 H'44 H'45 H'46 H'47 H'48 H'49 H'4A H'4B FLMCR1 FLMCR2 EBR1 EBR2 8 8 8 8 FWE FLER EB7 EB15 SWE1 SWE2 EB6 EB14 ESU1 ESU2 EB5 EB13 PSU1 PSU2 EB4 EB12 EV1 EV2 EB3 EB11 PV1 PV2 EB2 EB10 E1 E2 EB1 EB9 P1 P2 EB0 EB8 Reserved area (access prohibited) RAMCR 8 -- -- -- -- RAMS RAM2 RAM1 RAM0 Reserved area (access prohibited) Rev. 2.0, 03/01, page 696 of 822 Address Register (low) Name H'4C H'4D H'4E H'4F H'50 H'51 H'52 H'53 H'54 H'55 H'56 H'57 H'58 H'59 H'5A H'5B H'5C H'5D H'5E H'5F H'60 H'61 H'62 H'63 H'64 H'65 H'66 H'67 H'68 H'69 H'6A H'6B H'6C H'6D H'6E H'6F DASTCR DIVCR MSTCR CSCR TSTR TSNC TMDR TFCR TCR0 TIOR0 TIER0 TSR0 TCNT0H TCNT0L GRA0H GRA0L GRB0H GRB0L TCR1 TIOR1 Data Bus Width Bit 7 Bit Names Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Module Name Reserved area (access prohibited) 8 8 8 8 8 8 8 8 8 8 8 8 16 -- -- PSTOP CS7E -- -- -- -- -- -- -- -- -- -- -- CS6E -- -- MDF -- CCLR1 IOB2 -- -- -- -- -- -- -- -- -- -- -- DIV1 DASTE DIV0 D/A converter System control Bus controller ITU (all channels) MSTOP5 MSTOP4 MSTOP3 MSTOP2 MSTOP1 MSTOP0 CS5E -- -- FDIR CMD1 CCLR0 IOB1 -- -- CS4E STR4 SYNC4 PWM4 CMD0 CKEG1 IOB0 -- -- -- STR3 SYNC3 PWM3 BFB4 CKEG0 -- -- -- -- STR2 SYNC2 PWM2 BFA4 TPSC2 IOA2 OVIE OVF -- STR1 SYNC1 PWM1 BFB3 TPSC1 IOA1 IMIEB IMFB -- STR0 SYNC0 PWM0 BFA3 TPSC0 IOA0 IMIEA IMFA ITU channel 0 16 16 8 8 -- -- CCLR1 IOB2 CCLR0 IOB1 CKEG1 IOB0 CKEG0 -- TPSC2 IOA2 TPSC1 IOA1 TPSC0 IOA0 ITU channel 1 Rev. 2.0, 03/01, page 697 of 822 Address Register (low) Name H'70 H'71 H'72 H'73 H'74 H'75 H'76 H'77 H'78 H'79 H'7A H'7B H'7C H'7D H'7E H'7F H'80 H'81 H'82 H'83 H'84 H'85 H'86 H'87 H'88 H'89 H'8A H'8B H'8C H'8D H'8E H'8F H'90 H'91 H'92 H'93 TIER1 TSR1 TCNT1H TCNT1L GRA1H GRA1L GRB1H GRB1L TCR2 TIOR2 TIER2 TSR2 TCNT2H TCNT2L GRA2H GRA2L GRB2H GRB2L TCR3 TIOR3 TIER3 TSR3 TCNT3H TCNT3L GRA3H GRA3L GRB3H GRB3L BRA3H BRA3L BRB3H BRB3L TOER TOCR TCR4 TIOR4 Data Bus Width Bit 7 8 8 16 -- -- Bit Names Bit 6 -- -- Bit 5 -- -- Bit 4 -- -- Bit 3 -- -- Bit 2 OVIE OVF Bit 1 IMIEB IMFB Bit 0 IMIEA IMFA Module Name ITU channel 1 16 16 8 8 8 8 16 -- -- -- -- CCLR1 IOB2 -- -- CCLR0 IOB1 -- -- CKEG1 IOB0 -- -- CKEG0 -- -- -- TPSC2 IOA2 OVIE OVF TPSC1 IOA1 IMIEB IMFB TPSC0 IOA0 IMIEA IMFA ITU channel 2 16 16 8 8 8 8 16 -- -- -- -- CCLR1 IOB2 -- -- CCLR0 IOB1 -- -- CKEG1 IOB0 -- -- CKEG0 -- -- -- TPSC2 IOA2 OVIE OVF TPSC1 IOA1 IMIEB IMFB TPSC0 IOA0 IMIEA IMFA ITU channel 3 16 16 16 16 8 8 8 8 -- -- -- -- -- -- CCLR1 IOB2 EXB4 -- CCLR0 IOB1 EXA4 XTGD CKEG1 IOB0 EB3 -- CKEG0 -- EB4 -- TPSC2 IOA2 EA4 OLS4 TPSC1 IOA1 EA3 OLS3 TPSC0 IOA0 ITU (all channels) ITU channel 4 Rev. 2.0, 03/01, page 698 of 822 Address Register (low) Name H'94 H'95 H'96 H'97 H'98 H'99 H'9A H'9B H'9C H'9D H'9E H'9F H'A0 H'A1 H'A2 H'A3 H'A4 TIER4 TSR4 TCNT4H TCNT4L GRA4H GRA4L GRB4H GRB4L BRA4H BRA4L BRB4H BRB4L TPMR TPCR NDERB NDERA 1 NDRB* Data Bus Width Bit 7 8 8 16 -- -- Bit Names Bit 6 -- -- Bit 5 -- -- Bit 4 -- -- Bit 3 -- -- Bit 2 OVIE OVF Bit 1 IMIEB IMFB Bit 0 IMIEA IMFA Module Name ITU channel 4 16 16 16 16 8 8 8 8 8 8 -- -- -- -- G3NOV G2NOV G1NOV G0NOV TPC G3CMS1 G3CMS0 G2CMS1 G2CMS0 G1CMS1 G1CMS0 G0CMS1 G0CMS0 NDER15 NDER14 NDER13 NDER12 NDER11 NDER10 NDER9 NDER7 NDR15 NDR15 NDR7 NDR7 -- -- -- -- OVF NDER6 NDR14 NDR14 NDR6 NDR6 -- -- -- -- WT/,7 NDER5 NDR13 NDR13 NDR5 NDR5 -- -- -- -- TME NDER4 NDR12 NDR12 NDR4 NDR4 -- -- -- -- -- NDER3 NDR11 -- NDR3 -- -- NDR11 -- NDR3 -- NDER2 NDR10 -- NDR2 -- -- NDR10 -- NDR2 CKS2 NDER1 NDR9 -- NDR1 -- -- NDR9 -- NDR1 CKS1 NDER8 NDER0 NDR8 -- NDR0 -- -- NDR8 -- NDR0 CKS0 WDT H'A5 NDRA* 1 8 8 H'A6 NDRB* 1 8 8 H'A7 NDRA* 1 8 8 H'A8 H'A9 H'AA H'AB H'AC H'AD H'AE H'AF 2 TCSR* 2 TCNT* 8 8 -- 2 RSTCSR* 8 -- WRST SRFMD CMF -- -- -- -- -- -- -- -- -- -- RFSHE -- -- -- -- -- -- -- RCYCE -- Refresh controller RFSHCR RTMCSR RTCNT RTCOR 8 8 8 8 PSRAME DRAME CAS/:( M9/0; CMIE CKS2 CKS1 CKS0 Rev. 2.0, 03/01, page 699 of 822 Address Register (low) Name H'B0 H'B1 H'B2 H'B3 H'B4 H'B5 H'B6 H'B7 H'B8 H'B9 H'BA H'BB H'BC H'BD H'BE H'BF H'C0 H'C1 H'C2 H'C3 H'C4 H'C5 H'C6 H'C7 H'C8 H'C9 H'CA H'CB H'CC H'CD H'CE H'CF H'D0 H'D1 H'D2 H'D3 P1DDR P2DDR P1DR P2DR P3DDR P4DDR P3DR P4DR P5DDR P6DDR P5DR P6DR -- P8DDR P7DR P8DR P9DDR PADDR P9DR PADR SMR BRR SCR TDR SSR RDR SCMR Data Bus Width Bit 7 8 8 8 8 8 8 8 -- TDRE TIE C/$/GM Bit Names Bit 6 CHR Bit 5 PE Bit 4 O/( Bit 3 STOP Bit 2 MP Bit 1 CKS1 Bit 0 CKS0 Module Name SCI channel 0 RIE TE RE MPIE TEIE CKE1 CKE0 RDRF ORER FER/ ERS PER TEND MPB MPBT -- -- -- SDIR SINV -- SMIF Reserved area (access prohibited) SMR BRR SCR TDR SSR RDR 8 8 8 8 8 8 TDRE RDRF ORER FER PER TEND MPB MPBT TIE RIE TE RE MPIE TEIE CKE1 CKE0 C/$ CHR PE O/( STOP MP CKS1 CKS0 SCI channel 1 Reserved area (access prohibited) 8 8 8 8 8 8 8 8 8 8 8 8 P17DDR P16DDR P15DDR P14DDR P13DDR P12DDR P11DDR P10DDR Port 1 P27DDR P26DDR P25DDR P24DDR P23DDR P22DDR P21DDR P20DDR Port 2 P17 P27 P16 P26 P15 P25 P14 P24 P13 P23 P12 P22 P11 P21 P10 P20 Port 1 Port 2 P37DDR P36DDR P35DDR P34DDR P33DDR P32DDR P31DDR P30DDR Port 3 P47DDR P46DDR P45DDR P44DDR P43DDR P42DDR P41DDR P40DDR Port 4 P37 P47 -- -- -- -- -- P36 P46 -- P35 P45 -- P34 P44 -- P33 P43 P32 P42 P31 P41 P30 P40 Port 3 Port 4 P53DDR P52DDR P51DDR P50DDR Port 5 P66DDR P65DDR P64DDR P63DDR P62DDR P61DDR P60DDR Port 6 -- P66 -- -- P76 -- -- -- P65 -- -- P75 -- -- P64 -- P53 P63 -- P52 P62 -- P51 P61 -- P50 P60 -- Port 5 Port 6 8 8 8 8 8 8 8 -- P77 -- -- P84DDR P83DDR P82DDR P81DDR P80DDR Port 8 P74 P84 P73 P83 P72 P82 P71 P81 P70 P80 Port 7 Port 8 P95DDR P94DDR P93DDR P92DDR P91DDR P90DDR Port 9 PA7DDR PA6DDR PA5DDR PA4DDR PA3DDR PA2DDR PA1DDR PA0DDR Port A -- PA7 -- PA6 P95 PA5 P94 PA4 P93 PA3 P92 PA2 P91 PA1 P90 PA0 Port 9 Port A Rev. 2.0, 03/01, page 700 of 822 Address Register (low) Name H'D4 H'D5 H'D6 H'D7 H'D8 H'D9 H'DA H'DB H'DC H'DD H'DE H'DF H'E0 H'E1 H'E2 H'E3 H'E4 H'E5 H'E6 H'E7 H'E8 H'E9 H'EA H'EB H'EC H'ED H'EE H'EF H'F0 H'F1 H'F2 H'F3 H'F4 H'F5 H'F6 H'F7 H'F8 H'F9 ABWCR ASTCR WCR WCER PBDDR -- PBDR -- P2PCR -- P4PCR P5PCR DADR0 DADR1 DACR Data Bus Width Bit 7 8 -- 8 -- 8 Bit Names Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Module Name PB7DDR PB6DDR PB5DDR PB4DDR PB3DDR PB2DDR PB1DDR PB0DDR Port B -- PB7 -- -- PB6 -- -- PB5 -- -- PB4 -- -- PB3 -- -- PB2 -- -- PB1 -- -- PB0 -- -- Port B -- P27PCR P26PCR P25PCR P24PCR P23PCR P22PCR P21PCR P20PCR Port 2 -- -- -- -- -- -- -- -- 8 8 8 8 8 P47PCR P46PCR P45PCR P44PCR P43PCR P42PCR P41PCR P40PCR Port 4 -- -- -- -- P53PCR P52PCR P51PCR P50PCR Port 5 D/A converter DAOE1 DAOE0 DAE -- -- -- -- -- Reserved area (access prohibited) ADDRAH ADDRAL ADDRBH ADDRBL ADDRCH ADDRCL ADDRDH ADDRDL ADCSR ADCR 8 8 8 8 8 8 8 8 8 8 AD9 AD1 AD9 AD1 AD9 AD1 AD9 AD1 ADF TRGE AD8 AD0 AD8 AD0 AD8 AD0 AD8 AD0 ADIE -- AD7 -- AD7 -- AD7 -- AD7 -- ADST -- AD6 -- AD6 -- AD6 -- AD6 -- SCAN -- AD5 -- AD5 -- AD5 -- AD5 -- CKS -- AD4 -- AD4 -- AD4 -- AD4 -- CH2 -- AD3 -- AD3 -- AD3 -- AD3 -- CH1 -- AD2 -- AD2 -- AD2 -- AD2 -- CH0 -- A/D converter Reserved area (access prohibited) 8 8 8 8 ABW7 AST7 -- WCE7 ABW6 AST6 -- WCE6 ABW5 AST5 -- WCE5 ABW4 AST4 -- WCE4 ABW3 AST3 WMS1 WCE3 ABW2 AST2 WMS0 WCE2 ABW1 AST1 WC1 WCE1 ABW0 AST0 WC0 WCE0 Bus controller Reserved area (access prohibited) MDCR SYSCR BRCR ISCR IER ISR 8 8 8 8 8 8 -- SSBY A23E -- -- -- -- STS2 A22E -- -- -- -- STS1 A21E -- STS0 -- -- UE -- MDS2 NMIEG -- MDS1 -- -- MDS0 RAME BRLE System control Bus controller IRQ5SC IRQ4SC IRQ3SC IRQ2SC IRQ1SC IRQ0SC Interrupt controller IRQ5E IRQ4E IRQ3E IRQ2E IRQ1E IRQ0E IRQ5F IRQ4F IRQ3F IRQ2F IRQ1F IRQ0F Reserved area (access prohibited) IPRA IPRB 8 8 IPRA7 IPRB7 IPRA6 IPRB6 IPRA5 IPRB5 IPRA4 -- IPRA3 IPRB3 IPRA2 IPRB2 IPRA1 IPRB1 IPRA0 -- Rev. 2.0, 03/01, page 701 of 822 Address Register (low) Name H'FA H'FB H'FC H'FD H'FE H'FF Data Bus Width Bit 7 Bit Names Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Module Name Reserved area (access prohibited) Notes: 1. The address depends on the output trigger setting. 2. For write access to TCSR TCNT, and RSTCR see section 12.2.4, Notes on Register Access. Legend DMAC: DMA controller ITU: 16-bit integrated timer unit TPC: Programmable timing pattern controller WDT: Watchdog timer SCI: Serial communication interface Rev. 2.0, 03/01, page 702 of 822 B.2 Function Register name Address to which the register is mapped Name of on-chip supporting module Register acronym TSTR Timer Start Register H'60 ITU (all channels) Bit numbers Bit 7 -- Initial value Read/Write 1 -- 6 -- 1 -- 5 -- 1 -- 4 STR4 0 R/W 3 STR3 0 R/W 2 STR2 0 R/W 1 STR1 0 R/W 0 STR0 0 R/W Initial bit values Names of the bits. Dashes (--) indicate reserved bits. Possible types of access R W Read only Write only Counter start 0 0 TCNT0 is halted 1 TCNT0 is counting Counter start 1 0 TCNT1 is halted 1 TCNT1 is counting Counter start 2 0 TCNT2 is halted 1 TCNT2 is counting Counter start 3 0 TCNT3 is halted 1 TCNT3 is counting Counter start 4 0 TCNT4 is halted 1 TCNT4 is counting R/W Read and write Full name of bit Descriptions of bit settings Rev. 2.0, 03/01, page 703 of 822 MAR0A R/E/H/L--Memory Address Register 0A R/E/H/L H'20, H'21, H'22, H'23 22 21 20 19 18 DMAC0 Bit Initial value Read/Write 31 30 29 28 27 26 25 24 23 17 16 Undetermined -- -- -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MAR0AE MAR0AR Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MAR0AH Source or destination address MAR0AL Rev. 2.0, 03/01, page 704 of 822 ETCR0A H/L--Execute Transfer Count Register 0A H/L * Short address mode I/O mode and idle mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 H'24, H'25 DMAC0 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Transfer counter Repeat mode Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0AH Transfer counter Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0AL Initial count Rev. 2.0, 03/01, page 705 of 822 ETCR0A H/L--Execute Transfer Count Register 0A H/L (cont) * Full address mode Normal mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 H'24, H'25 DMAC0 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Transfer counter Block transfer mode Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0AH Block size counter Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0AL Initial block size Rev. 2.0, 03/01, page 706 of 822 IOAR0A--I/O Address Register 0A Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 H'26 2 1 DMAC0 0 Undetermined R/W R/W R/W R/W R/W Short address mode: source or destination address Full address mode: not used Rev. 2.0, 03/01, page 707 of 822 DTCR0A--Data Transfer Control Register 0A * Short address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 DTID 0 R/W 4 RPE 0 R/W 3 DTIE 0 R/W H'27 DMAC0 2 DTS2 0 R/W 1 DTS1 0 R/W 0 DTS0 0 R/W Data transfer select Bit 2 Bit 1 Bit 0 DTS2 DTS1 DTS0 0 0 0 1 0 1 1 0 0 1 1 1 0 1 Data Transfer Activation Source Compare match/input capture A interrupt from ITU channel 0 Compare match/input capture A interrupt from ITU channel 1 Compare match/input capture A interrupt from ITU channel 2 Compare match/input capture A interrupt from ITU channel 3 SCI0 transmit-data-empty interrupt SCI0 receive-data-full interrupt Transfer in full address mode Transfer in full address mode Data transfer interrupt enable 0 Interrupt requested by DTE bit is disabled 1 Interrupt requested by DTE bit is enabled Repeat enable RPE 0 1 DTIE 0 1 0 1 Description I/O mode Repeat mode Idle mode Data transfer increment/decrement 0 Incremented: If DTSZ = 0, MAR is incremented by 1 after each transfer If DTSZ = 1, MAR is incremented by 2 after each transfer 1 Decremented: If DTSZ = 0, MAR is decremented by 1 after each transfer If DTSZ = 1, MAR is decremented by 2 after each transfer Data transfer size 0 Byte-size transfer 1 Word-size transfer Data transfer enable 0 Data transfer is disabled 1 Data transfer is enabled Rev. 2.0, 03/01, page 708 of 822 DTCR0A--Data Transfer Control Register 0A (cont) * Full address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 SAID 0 R/W 4 SAIDE 0 R/W 3 DTIE 0 R/W H'27 DMAC0 2 DTS2A 0 R/W 1 DTS1A 0 R/W 0 DTS0A 0 R/W Data transfer select 0A 0 Normal mode 1 Block transfer mode Data transfer select 2A and 1A Set both bits to 1 Data transfer interrupt enable 0 Interrupt request by DTE bit is disabled 1 Interrupt request by DTE bit is enabled Source address increment/decrement (bit 5) Source address increment/decrement enable (bit 4) Bit 5 Bit 4 SAID SAIDE Increment/Decrement Enable 0 0 MARA is held fixed 1 Incremented: If DTSZ = 0, MARA is incremented by 1 after each transfer If DTSZ = 1, MARA is incremented by 2 after each transfer 1 0 MARA is held fixed 1 Decremented: If DTSZ = 0, MARA is decremented by 1 after each transfer If DTSZ = 1, MARA is decremented by 2 after each transfer Data transfer size 0 Byte-size transfer 1 Word-size transfer Data transfer enable 0 Data transfer is disabled 1 Data transfer is enabled Rev. 2.0, 03/01, page 709 of 822 MAR0B R/E/H/L--Memory Address Register 0B R/E/H/L H'28, H'29, H'2A, H'2B 22 21 20 19 18 DMAC0 Bit Initial value Read/Write 31 30 29 28 27 26 25 24 23 17 16 Undetermined -- -- -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MAR0BE MAR0BR Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MAR0BH Source or destination address MAR0BL Rev. 2.0, 03/01, page 710 of 822 ETCR0B H/L--Execute Transfer Count Register 0B H/L * Short address mode I/O mode and idle mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 H'2C, H'2D DMAC0 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Transfer counter Repeat mode Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0BH Transfer counter Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR0BL Initial count Rev. 2.0, 03/01, page 711 of 822 ETCR0B H/L--Execute Transfer Count Register 0B H/L (cont) * Full address mode Normal mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 H'2C, H'2D DMAC0 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Not used Block transfer mode Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Block transfer counter IOAR0B--I/O Address Register 0B Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 H'2E 2 1 DMAC0 0 Undetermined R/W R/W R/W R/W R/W Short address mode: source or destination address Full address mode: not used Rev. 2.0, 03/01, page 712 of 822 DTCR0B--Data Transfer Control Register 0B * Short address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 DTID 0 R/W 4 RPE 0 R/W 3 DTIE 0 R/W H'2F DMAC0 2 DTS2 0 R/W 1 DTS1 0 R/W 0 DTS0 0 R/W Data transfer select Bit 2 Bit 1 Bit 0 DTS2 DTS1 DTS0 0 0 0 1 0 1 1 0 0 1 1 0 1 1 Data Transfer Activation Source Compare match/input capture A interrupt from ITU channel 0 Compare match/input capture A interrupt from ITU channel 1 Compare match/input capture A interrupt from ITU channel 2 Compare match/input capture A interrupt from ITU channel 3 SCI0 transmit-data-empty interrupt SCI0 receive-data-full interrupt Falling edge of input Low level of input Data transfer interrupt enable 0 Interrupt requested by DTE bit is disabled 1 Interrupt requested by DTE bit is enabled An interrupt request is issued to the CPU when the DTE bit = 0 Repeat enable RPE DTIE Description 0 0 I/O mode 1 0 1 Repeat mode 1 Idle mode Data transfer increment/decrement 0 Incremented: If DTSZ = 0, MAR is incremented by 1 after each transfer If DTSZ = 1, MAR is incremented by 2 after each transfer 1 Decremented: If DTSZ = 0, MAR is decremented by 1 after each transfer If DTSZ = 1, MAR is decremented by 2 after each transfer Data transfer size 0 Byte-size transfer 1 Word-size transfer Data transfer enable 0 Data transfer is disabled 1 Data transfer is enabled Rev. 2.0, 03/01, page 713 of 822 DTCR0B--Data Transfer Control Register 0B (cont) * Full address mode Bit Initial value Read/Write 7 DTME 0 R/W 6 -- 0 R/W 5 DAID 0 R/W 4 DAIDE 0 R/W 3 TMS 0 R/W H'2F DMAC0 2 DTS2B 0 R/W 1 DTS1B 0 R/W 0 DTS0B 0 R/W Data transfer select 2B to 0B Bit 2 Bit 1 Bit 0 Data Transfer Activation Source DTS2B DTS1B DTS0B Normal Mode Block Transfer Mode 0 0 0 Auto-request Compare match/input capture (burst mode) A from ITU channel 0 Not available Compare match/input capture 1 A from ITU channel 1 Compare match/input capture Auto-request 0 1 A from ITU channel 2 (cycle-steal mode) Compare match/input capture Not available 1 A from ITU channel 3 1 Not available Not available 0 0 Not available Not available 1 Falling edge of Falling edge of 1 0 Not available 1 Low level input at Transfer mode select 0 Destination is the block area in block transfer mode 1 Source is the block area in block transfer mode Destination address increment/decrement (bit 5) Destination address increment/decrement enable (bit 4) Bit 5 Bit 4 DAID DAIDE Increment/Decrement Enable 0 0 MARB is held fixed 1 Incremented: If DTSZ = 0, MARB is incremented by 1 after each transfer If DTSZ = 1, MARB is incremented by 2 after each transfer 1 0 MARB is held fixed 1 Decremented: If DTSZ = 0, MARB is decremented by 1 after each transfer If DTSZ = 1, MARB is decremented by 2 after each transfer Data transfer master enable 0 Data transfer is disabled 1 Data transfer is enabled Rev. 2.0, 03/01, page 714 of 822 MAR1A R/E/H/L--Memory Address Register 1A R/E/H/L H'30, H'31, H'32, H'33 22 21 20 19 18 DMAC1 Bit Initial value Read/Write 31 30 29 28 27 26 25 24 23 17 16 Undetermined -- -- -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MAR1AE MAR1AR Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MAR1AH MAR1AL Note: Bit functions are the same as for DMAC0. Rev. 2.0, 03/01, page 715 of 822 ETCR1A H/L--Execute Transfer Count Register 1A H/L Bit Initial value Read/Write Bit Initial value Read/Write R/W R/W R/W 15 14 13 12 11 10 9 8 7 6 H'34, H'35 5 4 3 2 DMAC1 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR1AH Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR1AL Note: Bit functions are the same as for DMAC0. IOAR1A--I/O Address Register 1A Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 H'36 2 1 DMAC1 0 Undetermined R/W R/W R/W R/W R/W Note: Bit functions are the same as for DMAC0. Rev. 2.0, 03/01, page 716 of 822 DTCR1A--Data Transfer Control Register 1A * Short address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 DTID 0 R/W 4 RPE 0 R/W 3 DTIE 0 R/W H'37 DMAC1 2 DTS2 0 R/W 1 DTS1 0 R/W 0 DTS0 0 R/W * Full address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 SAID 0 R/W 4 SAIDE 0 R/W 3 DTIE 0 R/W 2 DTS2A 0 R/W 1 DTS1A 0 R/W 0 DTS0A 0 R/W Note: Bit functions are the same as for DMAC0. MAR1B R/E/H/L--Memory Address Register 1B R/E/H/L H'38, H'39, H'3A, H'3B 22 21 20 19 18 DMAC1 Bit Initial value Read/Write 31 30 29 28 27 26 25 24 23 17 16 Undetermined -- -- -- -- -- -- -- Undetermined -- R/W R/W R/W R/W R/W R/W R/W R/W MAR1BE MAR1BR Bit Initial value Read/Write 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Undetermined Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W MAR1BH MAR1BL Note: Bit functions are the same as for DMAC0. Rev. 2.0, 03/01, page 717 of 822 ETCR1B H/L--Execute Transfer Count Register 1B H/L Bit Initial value Read/Write Bit Initial value Read/Write R/W R/W R/W 15 14 13 12 11 10 9 8 7 6 H'3C, H'3D 5 4 3 2 DMAC1 1 0 Undetermined R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR1BH Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 2 1 0 Undetermined R/W R/W R/W R/W R/W ETCR1BL Note: Bit functions are the same as for DMAC0. IOAR1B--I/O Address Register 1B Bit Initial value Read/Write R/W R/W R/W 7 6 5 4 3 H'3E 2 1 DMAC1 0 Undetermined R/W R/W R/W R/W R/W Note: Bit functions are the same as for DMAC0. Rev. 2.0, 03/01, page 718 of 822 DTCR1B--Data Transfer Control Register 1B * Short address mode Bit Initial value Read/Write 7 DTE 0 R/W 6 DTSZ 0 R/W 5 DTID 0 R/W 4 RPE 0 R/W 3 DTIE 0 R/W H'3F DMAC1 2 DTS2 0 R/W 1 DTS1 0 R/W 0 DTS0 0 R/W * Full address mode Bit Initial value Read/Write 7 DTME 0 R/W 6 -- 0 R/W 5 DAID 0 R/W 4 DAIDE 0 R/W 3 TMS 0 R/W 2 DTS2B 0 R/W 1 DTS1B 0 R/W 0 DTS0B 0 R/W Note: Bit functions are the same as for DMAC0. Rev. 2.0, 03/01, page 719 of 822 FLMCR1--Flash Memory Control Register 1 Bit Initial value* Read/Write 7 FWE 1 R 6 SWE1 0 R/W* 5 ESU1 0 R/W* 4 PSU1 0 R/W* 3 EV1 0 R/W* H'40 2 PV1 0 R/W* 1 Flash memory 0 P1 E1 0 R/W* 0 R/W* Program mode 1 0 1 Program mode cleared (Initial value) Transition to program mode Erase mode 1 0 1 0 1 Erase mode cleared (Initial value) Transition to erase mode (Initial value) Program-verify mode 1 Program-verify mode cleared Transition to program-verify mode Erase-verify mode 1 0 1 Erase-verify mode cleared (Initial value) Transition to erase-verify mode Program setup bit 1 0 1 Program setup cleared Program setup (Initial value) Erase setup bit 1 0 1 0 1 Erase setup cleared Erase setup (Initial value) (Initial value) Software write enable bit 1 Write disabled Write enabled Flash write enable bit 0 1 When a low level is input to the FWE pin (hardware protection state) When a high level is input to the FWE pin Note: * The initial value is H'00 in modes 5, 6, and 7 (on-chip flash memory enabled). In modes 1, 2, 3, and 4 (on-chip flash memory disabled), this register cannot be modified and is always read as H'FF. Rev. 2.0, 03/01, page 720 of 822 FLMCR2--Flash Memory Control Register 2 Bit Initial value* Read/Write 7 FLER 0 R 6 SWE2 0 R/W* 5 ESU2 0 R/W* 4 PSU2 0 R/W* 3 EV2 0 R/W* H'41 2 PV2 0 R/W* 1 Flash memory 0 P2 E2 0 R/W* 0 R/W* Program mode 2 0 1 Program mode cleared (Initial value) Transition to program mode Erase mode 2 0 1 0 1 Erase mode cleared (Initial value) Transition to erase mode (Initial value) Program-verify mode 2 Program-verify mode cleared Transition to program-verify mode Erase-verify mode 2 0 1 Erase-verify mode cleared (Initial value) Transition to erase-verify mode Program setup bit 2 0 1 Program setup cleared Program setup (Initial value) Erase setup bit 2 0 1 0 1 Erase setup cleared Erase setup (Initial value) (Initial value) Software write enable bit 2 Write disabled Write enabled Flash memory error 0 1 Flash memory is operating normally Flash memory program/erase protection (error protection) is disabled An error occurred during flash memory programming/erasing Flash memory program/erase protection (error protection) is enabled (Initial value) Note: * The initial value is H'00 in modes 5, 6, and 7 (on-chip flash memory enabled). In modes 1, 2, 3, and 4 (on-chip flash memory disabled), this register cannot be modified and is always read as H'FF. Rev. 2.0, 03/01, page 721 of 822 EBR1--Erase Block Register 1 Bit Initial value* Read/Write 7 EB7 0 R/W* 6 EB6 0 R/W* 5 EB5 0 R/W* 4 EB4 0 R/W* 3 EB3 0 R/W* H'42 2 EB2 0 R/W* Flash memory 1 EB1 0 R/W* 0 EB1 0 R/W* Erase block specification bits (1) 0 Erase protection state 1 Erasable state Note: * The initial value is H'00 in modes 5, 6 and 7 (on-chip ROM enabled). In modes 1, 2, 3, and 4 (on-chip ROM disabled), this register cannot be modified and is always read as H'FF. EBR2--Erase Block Register 2 Bit Initial value* Read/Write 7 EB15 0 R/W* 6 EB14 0 R/W* 5 EB13 0 R/W* 4 EB12 0 R/W* 3 EB11 0 R/W* H'43 2 EB10 0 R/W* Flash memory 1 EB9 0 R/W* 0 EB8 0 R/W* Erase block specification bits (2) 0 Erase protection state 1 Erasable state Note: * The initial value is H'00 in modes 5, 6 and 7 (on-chip ROM enabled). In modes 1, 2, 3, and 4 (on-chip ROM disabled), this register cannot be modified and is always read as H'FF. Rev. 2.0, 03/01, page 722 of 822 RAMCR--RAM Control Register Bit Initial value* Read/Write 7 -- H'47 5 -- Flash memory 1 RAM1 0 R/W 0 RAM0 0 R/W 6 -- 4 -- 3 RAMS 0 R/W 2 RAM2 0 R/W 1 R 1 R 1 R 1 R RAM select, RAM 2 to RAM 0 Bit 0 Bit 1 Bit 3 Bit 2 RAMS RAM 2 RAM 1 RAM 0 1/0 1/0 0 1/0 1 0 0 0 1 0 1 1 0 1 0 1 0 1 1 RAM Area H'FFE000 to H'FFEFFF H'000000 to H'000FFF H'001000 to H'001FFF H'002000 to H'002FFF H'003000 to H'003FFF H'004000 to H'004FFF H'005000 to H'005FFF H'006000 to H'006FFF H'007000 to H'007FFF Rev. 2.0, 03/01, page 723 of 822 DASTCR--D/A Standby Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'5C 2 -- 1 -- System control 1 -- 1 -- 0 DASTE 0 R/W D/A standby enable 0 D/A output is disabled in software standby mode 1 D/A output is enabled in software standby mode DIVCR--Division Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 7 -- 1 -- 3 -- 1 -- H'5D 2 -- 1 -- System control 1 DIV1 0 R/W 0 DIV0 0 R/W Divide 1 and 0 Bit 1 Bit 0 DIV1 DIV0 0 0 1 0 1 1 Frequency Division Ratio 1/1 (Initial value) 1/2 1/4 1/8 Rev. 2.0, 03/01, page 724 of 822 MSTCR--Module Standby Control Register Bit Initial value Read/Write 7 PSTOP 0 R/W 6 -- 1 -- 5 0 R/W 4 0 R/W 3 0 R/W H'5E 2 0 R/W 1 0 System control 0 0 R/W MSTOP5 MSTOP4 MSTOP3 MSTOP2 MSTOP1 MSTOP0 R/W Module standby 0 0 A/D converter operates normally (Initial value) 1 A/D converter is in standby state Module standby 1 0 Refresh controller operates normally 1 Refresh controller is in standby state Module standby 2 0 DMAC operates normally 1 DMAC is in standby state Module standby 3 0 SCI1 operates normally 1 SCI1 is in standby state Module standby 4 0 SCI0 operates normally 1 SCI0 is in standby state Module standby 5 0 ITU operates normally 1 ITU is in standby state o clock stop 0 o clock output is enabled (Initial value) 1 o clock output is disabled (Initial value) (Initial value) (Initial value) (Initial value) (Initial value) Rev. 2.0, 03/01, page 725 of 822 CSCR--Chip Select Control Register Bit Initial value Read/Write 7 CS7E 0 R/W 6 CS6E 0 R/W 5 CS5E 0 R/W 4 CS4E 0 R/W 3 -- 1 -- H'5F 2 -- 1 -- System control 1 -- 1 -- 0 -- 1 -- Chip select 7 to 4 enable Bit n CSnE Description 0 Output of chip select signal CSn is disabled Output of chip select signal CSn is enabled 1 (Initial value) (n = 7 to 4) Rev. 2.0, 03/01, page 726 of 822 TSTR--Timer Start Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 STR4 0 R/W 3 STR3 0 R/W H'60 2 STR2 0 R/W ITU (all channels) 1 STR1 0 R/W 0 STR0 0 R/W Counter start 0 0 TCNT0 is halted 1 TCNT0 is counting Counter start 1 0 TCNT1 is halted 1 TCNT1 is counting Counter start 2 0 TCNT2 is halted 1 TCNT2 is counting Counter start 3 0 TCNT3 is halted 1 TCNT3 is counting Counter start 4 0 TCNT4 is halted 1 TCNT4 is counting Rev. 2.0, 03/01, page 727 of 822 TSNC--Timer Synchro Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 SYNC4 0 R/W 3 SYNC3 0 R/W H'61 2 SYNC2 0 R/W ITU (all channels) 1 SYNC1 0 R/W 0 SYNC0 0 R/W Timer sync 0 0 TCNT0 operates independently 1 TCNT0 is synchronized Timer sync 1 0 TCNT1 operates independently 1 TCNT1 is synchronized Timer sync 2 0 TCNT2 operates independently 1 TCNT2 is synchronized Timer sync 3 0 TCNT3 operates independently 1 TCNT3 is synchronized Timer sync 4 0 TCNT4 operates independently 1 TCNT4 is synchronized Rev. 2.0, 03/01, page 728 of 822 TMDR--Timer Mode Register Bit Initial value Read/Write 7 -- 1 -- 6 MDF 0 R/W 5 FDIR 0 R/W 4 PWM4 0 R/W 3 PWM3 0 R/W H'62 2 PWM2 0 R/W ITU (all channels) 1 PWM1 0 R/W 0 PWM0 0 R/W PWM mode 0 0 Channel 0 operates normally 1 Channel 0 operates in PWM mode PWM mode 1 0 Channel 1 operates normally 1 Channel 1 operates in PWM mode PWM mode 2 0 Channel 2 operates normally 1 Channel 2 operates in PWM mode PWM mode 3 0 Channel 3 operates normally 1 Channel 3 operates in PWM mode PWM mode 4 0 Channel 4 operates normally 1 Channel 4 operates in PWM mode Flag direction 0 OVF is set to 1 in TSR2 when TCNT2 overflows or underflows 1 OVF is set to 1 in TSR2 when TCNT2 overflows Phase counting mode flag 0 Channel 2 operates normally 1 Channel 2 operates in phase counting mode Rev. 2.0, 03/01, page 729 of 822 TFCR--Timer Function Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 CMD1 0 R/W 4 CMD0 0 R/W 3 BFB4 0 R/W H'63 2 BFA4 0 R/W ITU (all channels) 1 BFB3 0 R/W 0 BFA3 0 R/W Buffer mode A3 0 GRA3 operates normally 1 GRA3 is buffered by BRA3 Buffer mode B3 0 GRB3 operates normally 1 GRB3 is buffered by BRB3 Buffer mode A4 0 GRA4 operates normally 1 GRA4 is buffered by BRA4 Buffer mode B4 0 GRB4 operates normally 1 GRB4 is buffered by BRB4 Combination mode 1 and 0 Bit 5 Bit 4 CMD1 CMD0 Operating Mode of Channels 3 and 4 0 0 Channels 3 and 4 operate normally 1 0 1 Channels 3 and 4 operate together in complementary PWM mode 1 Channels 3 and 4 operate together in reset-synchronized PWM mode Rev. 2.0, 03/01, page 730 of 822 TCR0--Timer Control Register 0 Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 0 R/W 3 0 R/W H'64 2 TPSC2 0 R/W 1 TPSC1 0 R/W ITU0 0 TPSC0 0 R/W CKEG1 CKEG0 Timer prescaler 2 to 0 Bit 2 Bit 0 Bit 1 TPSC2 TPSC1 TPSC0 0 0 0 1 0 1 1 0 0 1 1 0 1 1 Clock edge 1 and 0 Bit 4 Bit 3 CKEG1 CKEG0 0 0 1 1 -- Counted Edges of External Clock Rising edges counted Falling edges counted Both edges counted TCNT Clock Source Internal clock: o Internal clock: o/2 Internal clock: o/4 Internal clock: o/8 External clock A: TCLKA input External clock B: TCLKB input External clock C: TCLKC input External clock D: TCLKD input Counter clear 1 and 0 Bit 6 Bit 5 CCLR1 CCLR0 TCNT Clear Source 0 0 TCNT is not cleared 1 TCNT is cleared by GRA compare match or input capture 0 1 TCNT is cleared by GRB compare match or input capture 1 Synchronous clear: TCNT is cleared in synchronization with other synchronized timers Rev. 2.0, 03/01, page 731 of 822 TIOR0--Timer I/O Control Register 0 Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- H'65 2 IOA2 0 R/W 1 IOA1 0 R/W ITU0 0 IOA0 0 R/W I/O control A2 to A0 Bit 2 Bit 1 Bit 0 IOA2 IOA1 IOA0 0 0 0 1 0 1 1 0 0 1 1 0 1 1 I/O control B2 to B0 Bit 6 Bit 5 Bit 4 IOB2 IOB1 IOB0 0 0 0 1 0 1 1 0 0 1 1 0 1 1 GRA Function GRA is an output compare register GRA is an input capture register No output at compare match 0 output at GRA compare match 1 output at GRA compare match Output toggles at GRA compare match GRA captures rising edge of input GRA captures falling edge of input GRA captures both edges of input GRB Function GRB is an output compare register GRB is an input capture register No output at compare match 0 output at GRB compare match 1 output at GRB compare match Output toggles at GRB compare match GRB captures rising edge of input GRB captures falling edge of input GRB captures both edges of input Rev. 2.0, 03/01, page 732 of 822 TIER0--Timer Interrupt Enable Register 0 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'66 2 OVIE 0 R/W 1 IMIEB 0 R/W ITU0 0 IMIEA 0 R/W Input capture/compare match interrupt enable A 0 IMIA interrupt requested by IMFA flag is disabled 1 IMIA interrupt requested by IMFA flag is enabled Input capture/compare match interrupt enable B 0 IMIB interrupt requested by IMFB flag is disabled 1 IMIB interrupt requested by IMFB flag is enabled Overflow interrupt enable 0 OVI interrupt requested by OVF flag is disabled 1 OVI interrupt requested by OVF flag is enabled Rev. 2.0, 03/01, page 733 of 822 TSR0--Timer Status Register 0 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'67 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* ITU0 0 IMFA 0 R/(W)* Input capture/compare match flag A 0 [Clearing condition] Read IMFA when IMFA = 1, then write 0 in IMFA 1 [Setting conditions] TCNT = GRA when GRA functions as an output compare register. TCNT value is transferred to GRA by an input capture signal, when GRA functions as an input capture register. Input capture/compare match flag B 0 [Clearing condition] Read IMFB when IMFB = 1, then write 0 in IMFB 1 [Setting conditions] TCNT = GRB when GRB functions as an output compare register. TCNT value is transferred to GRB by an input capture signal, when GRB functions as an input capture register. Overflow flag 0 [Clearing condition] Read OVF when OVF = 1, then write 0 in OVF 1 [Setting condition] TCNT overflowed from H'FFFF to H'0000 or underflowed from H'0000 to H'FFFF Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 734 of 822 TCNT0 H/L--Timer Counter 0 H/L Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 H'68, H'69 5 0 4 0 3 0 2 0 1 0 ITU0 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Up-counter GRA0 H/L--General Register A0 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'6A, H'6B 5 1 4 1 3 1 2 1 1 1 ITU0 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Output compare or input capture register GRB0 H/L--General Register B0 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'6C, H'6D 5 1 4 1 3 1 2 1 1 1 ITU0 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Output compare or input capture register TCR1--Timer Control Register 1 Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 0 R/W 3 0 R/W H'6E 2 TPSC2 0 R/W 1 TPSC1 0 R/W ITU1 0 TPSC0 0 R/W CKEG1 CKEG0 Note: Bit functions are the same as for ITU0. Rev. 2.0, 03/01, page 735 of 822 TIOR1--Timer I/O Control Register 1 Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- H'6F 2 IOA2 0 R/W 1 IOA1 0 R/W ITU1 0 IOA0 0 R/W Note: Bit functions are the same as for ITU0. TIER1--Timer Interrupt Enable Register 1 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'70 2 OVIE 0 R/W 1 IMIEB 0 R/W ITU1 0 IMIEA 0 R/W Note: Bit functions are the same as for ITU0. TSR1--Timer Status Register 1 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'71 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* ITU1 0 IMFA 0 R/(W)* Notes: Bit functions are the same as for ITU0. * Only 0 can be written, to clear the flag. TCNT1 H/L--Timer Counter 1 H/L Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 H'72, H'73 5 0 4 0 3 0 2 0 1 0 ITU1 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU0. Rev. 2.0, 03/01, page 736 of 822 GRA1 H/L--General Register A1 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'74, H'75 5 1 4 1 3 1 2 1 1 1 ITU1 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU0. GRB1 H/L--General Register B1 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'76, H'77 5 1 4 1 3 1 2 1 1 1 ITU1 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU0. TCR2--Timer Control Register 2 Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 0 R/W 3 0 R/W H'78 2 TPSC2 0 R/W 1 TPSC1 0 R/W 0 ITU2 CKEG1 CKEG0 TPSC0 0 R/W Notes: 1. Bit functions are the same as for ITU0. 2. When channel 2 is used in phase counting mode, the counter clock source selection by bits TPSC2 to TPSC0 is ignored. Rev. 2.0, 03/01, page 737 of 822 TIOR2--Timer I/O Control Register 2 Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- H'79 2 IOA2 0 R/W 1 IOA1 0 R/W ITU2 0 IOA0 0 R/W Note: Bit functions are the same as for ITU0. TIER2--Timer Interrupt Enable Register 2 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'7A 2 OVIE 0 R/W 1 IMIEB 0 R/W ITU2 0 IMIEA 0 R/W Note: Bit functions are the same as for ITU0. TSR2--Timer Status Register 2 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'7B 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* 0 ITU2 IMFA 0 R/(W)* Note: * Only 0 can be written, to clear the flag. The function is the same as ITU0. Overflow flag 0 [Clearing condition] Read OVF when OVF = 1, then write 0 in OVF. 1 [Setting condition] The TCNT value overflows (from H'FFFF to H'0000) or underflows (from H'0000 to H'FFFF) Rev. 2.0, 03/01, page 738 of 822 TCNT2 H/L--Timer Counter 2 H/L Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 H'7C, H'7D 5 0 4 0 3 0 2 0 1 0 ITU2 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Phase counting mode: up/down counter Other modes: up-counter GRA2 H/L--General Register A2 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'7E, H'7F 5 1 4 1 3 1 2 1 1 1 ITU2 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU0. GRB2 H/L--General Register B2 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'80, H'81 5 1 4 1 3 1 2 1 1 1 ITU2 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU0. Rev. 2.0, 03/01, page 739 of 822 TCR3--Timer Control Register 3 Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 0 R/W 3 0 R/W H'82 2 TPSC2 0 R/W 1 TPSC1 0 R/W ITU3 0 TPSC0 0 R/W CKEG1 CKEG0 Note: Bit functions are the same as for ITU0. TIOR3--Timer I/O Control Register 3 Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- H'83 2 IOA2 0 R/W 1 IOA1 0 R/W ITU3 0 IOA0 0 R/W Note: Bit functions are the same as for ITU0. TIER3--Timer Interrupt Enable Register 3 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'84 2 OVIE 0 R/W 1 IMIEB 0 R/W ITU3 0 IMIEA 0 R/W Note: Bit functions are the same as for ITU0. Rev. 2.0, 03/01, page 740 of 822 TSR3--Timer Status Register 3 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'85 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* ITU3 0 IMFA 0 R/(W)* Overflow flag Bit functions are the same as for ITU0 0 [Clearing condition] Read OVF when OVF = 1, then write 1 in OVF 1 [Setting condition] TCNT overflowed from H'FFFF to H'0000 or underflowed from H'0000 to H'FFFF Note: * Only 0 can be written, to clear the flag. TCNT3 H/L--Timer Counter 3 H/L Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 H'86, H'87 5 0 4 0 3 0 2 0 1 0 ITU3 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Complementary PWM mode: up/down counter up-counter Other modes: GRA3 H/L--General Register A3 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'88, H'89 5 1 4 1 3 1 2 1 1 1 ITU3 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Output compare or input capture register (can be buffered) Rev. 2.0, 03/01, page 741 of 822 GRB3 H/L--General Register B3 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'8A, H'8B 5 1 4 1 3 1 2 1 1 1 ITU3 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Output compare or input capture register (can be buffered) BRA3 H/L--Buffer Register A3 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'8C, H'8D 5 1 4 1 3 1 2 1 1 1 ITU3 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Used in combination with GRA when buffer operation is selected BRB3 H/L--Buffer Register B3 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'8E, H'8F 5 1 4 1 3 1 2 1 1 1 ITU3 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Used in combination with GRB when buffer operation is selected Rev. 2.0, 03/01, page 742 of 822 TOER--Timer Output Enable Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 EXB4 1 R/W 4 EXA4 1 R/W 3 EB3 1 R/W H'90 2 EB4 1 R/W ITU (all channels) 1 EA4 1 R/W 0 EA3 1 R/W Master enable TIOCA3 0 TIOCA 3 output is disabled regardless of TIOR3, TMDR, and TFCR settings 1 TIOCA 3 is enabled for output according to TIOR3, TMDR, and TFCR settings Master enable TIOCA4 0 TIOCA 4 output is disabled regardless of TIOR4, TMDR, and TFCR settings 1 TIOCA 4 is enabled for output according to TIOR4, TMDR, and TFCR settings Master enable TIOCB4 0 TIOCB4 output is disabled regardless of TIOR4 and TFCR settings 1 TIOCB4 is enabled for output according to TIOR4 and TFCR settings Master enable TIOCB3 0 TIOCB 3 output is disabled regardless of TIOR3 and TFCR settings 1 TIOCB 3 is enabled for output according to TIOR3 and TFCR settings Master enable TOCXA4 0 TOCXA 4 output is disabled regardless of TFCR settings 1 TOCXA 4 is enabled for output according to TFCR settings Master enable TOCXB4 0 TOCXB4 output is disabled regardless of TFCR settings 1 TOCXB4 is enabled for output according to TFCR settings Rev. 2.0, 03/01, page 743 of 822 TOCR--Timer Output Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 XTGD 1 R/W 3 -- 1 -- H'91 2 -- 1 -- ITU (all channels) 1 OLS4 1 R/W 0 OLS3 1 R/W Output level select 3 0 TIOCB 3 , TOCXA 4 , and TOCXB 4 outputs are inverted 1 TIOCB 3 , TOCXA 4 , and TOCXB 4 outputs are not inverted Output level select 4 0 TIOCA 3 , TIOCA 4, and TIOCB4 outputs are inverted 1 TIOCA 3 , TIOCA 4, and TIOCB4 outputs are not inverted External trigger disable 0 Input capture A in channel 1 is used as an external trigger signal in reset-synchronized PWM mode and complementary PWM mode * 1 External triggering is disabled Note: * When an external trigger occurs, bits 5 to 0 in TOER are cleared to 0, disabling ITU output. Rev. 2.0, 03/01, page 744 of 822 TCR4--Timer Control Register 4 Bit Initial value Read/Write 7 -- 1 -- 6 CCLR1 0 R/W 5 CCLR0 0 R/W 4 0 R/W 3 0 R/W H'92 2 TPSC2 0 R/W 1 TPSC1 0 R/W ITU4 0 TPSC0 0 R/W CKEG1 CKEG0 Note: Bit functions are the same as for ITU0. TIOR4--Timer I/O Control Register 4 Bit Initial value Read/Write 7 -- 1 -- 6 IOB2 0 R/W 5 IOB1 0 R/W 4 IOB0 0 R/W 3 -- 1 -- H'93 2 IOA2 0 R/W 1 IOA1 0 R/W ITU4 0 IOA0 0 R/W Note: Bit functions are the same as for ITU0. TIER4--Timer Interrupt Enable Register 4 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'94 2 OVIE 0 R/W 1 IMIEB 0 R/W ITU4 0 IMIEA 0 R/W Note: Bit functions are the same as for ITU0. TSR4--Timer Status Register 4 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'95 2 OVF 0 R/(W)* 1 IMFB 0 R/(W)* ITU4 0 IMFA 0 R/(W)* Notes: Bit functions are the same as for ITU0. * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 745 of 822 TCNT4 H/L--Timer Counter 4 H/L Bit Initial value Read/Write 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 H'96, H'97 5 0 4 0 3 0 2 0 1 0 ITU4 0 0 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU3. GRA4 H/L--General Register A4 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'98, H'99 5 1 4 1 3 1 2 1 1 1 ITU4 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU3. GRB4 H/L--General Register B4 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'9A, H'9B 5 1 4 1 3 1 2 1 1 1 ITU4 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU3. BRA4 H/L--Buffer Register A4 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'9C, H'9D 5 1 4 1 3 1 2 1 1 1 ITU4 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU3. Rev. 2.0, 03/01, page 746 of 822 BRB4 H/L--Buffer Register B4 H/L Bit Initial value Read/Write 15 1 14 1 13 1 12 1 11 1 10 1 9 1 8 1 7 1 6 1 H'9E, H'9F 5 1 4 1 3 1 2 1 1 1 ITU4 0 1 R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Note: Bit functions are the same as for ITU3. TPMR--TPC Output Mode Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 0 R/W H'A0 2 0 R/W 1 0 R/W 0 0 TPC G3NOV G2NOV G1NOV G0NOV R/W Group 0 non-overlap 0 Normal TPC output in group 0 Output values change at compare match A in the selected ITU channel 1 Non-overlapping TPC output in group 0, controlled by compare match A and B in the selected ITU channel Group 1 non-overlap 0 Normal TPC output in group 1 Output values change at compare match A in the selected ITU channel 1 Non-overlapping TPC output in group 1, controlled by compare match A and B in the selected ITU channel Group 2 non-overlap 0 Normal TPC output in group 2 Output values change at compare match A in the selected ITU channel 1 Non-overlapping TPC output in group 2, controlled by compare match A and B in the selected ITU channel Group 3 non-overlap 0 Normal TPC output in group 3 Output values change at compare match A in the selected ITU channel 1 Non-overlapping TPC output in group 3, controlled by compare match A and B in the selected ITU channel Rev. 2.0, 03/01, page 747 of 822 TPCR--TPC Output Control Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'A1 2 1 R/W 1 1 R/W 0 1 TPC G3CMS1 G3CMS0 G2CMS1 G2CMS0 G1CMS1 G1CMS0 G0CMS1 G0CMS0 R/W Group 0 compare match select 1 and 0 Bit 1 Bit 0 G0CMS1 G0CMS0 0 0 1 1 0 1 ITU Channel Selected as Output Trigger TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 0 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 1 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 2 TPC output group 0 (TP3 to TP0) is triggered by compare match in ITU channel 3 Group 1 compare match select 1 and 0 Bit 3 Bit 2 G1CMS1 G1CMS0 0 0 1 1 0 1 ITU Channel Selected as Output Trigger TPC output group 1 (TP7 to TP4 ) is triggered by compare match in ITU channel 0 TPC output group 1 (TP7 to TP4 ) is triggered by compare match in ITU channel 1 TPC output group 1 (TP7 to TP4 ) is triggered by compare match in ITU channel 2 TPC output group 1 (TP7 to TP4 ) is triggered by compare match in ITU channel 3 Group 2 compare match select 1 and 0 Bit 5 Bit 4 G2CMS1 G2CMS0 0 0 1 0 1 1 ITU Channel Selected as Output Trigger TPC output group 2 (TP11 to TP8 ) is triggered by compare match in ITU channel 0 TPC output group 2 (TP11 to TP8 ) is triggered by compare match in ITU channel 1 TPC output group 2 (TP11 to TP8 ) is triggered by compare match in ITU channel 2 TPC output group 2 (TP11 to TP8 ) is triggered by compare match in ITU channel 3 Group 3 compare match select 1 and 0 Bit 7 Bit 6 G3CMS1 G3CMS0 0 0 1 0 1 1 ITU Channel Selected as Output Trigger TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 0 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 1 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 2 TPC output group 3 (TP15 to TP12) is triggered by compare match in ITU channel 3 Rev. 2.0, 03/01, page 748 of 822 NDERB--Next Data Enable Register B Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'A2 2 0 R/W 1 0 R/W 0 0 TPC NDER15 NDER14 NDER13 NDER12 NDER11 NDER10 NDER9 NDER8 R/W Next data enable 15 to 8 Bits 7 to 0 NDER15 to NDER8 Description 0 TPC outputs TP15 to TP8 are disabled (NDR15 to NDR8 are not transferred to PB 7 to PB 0 ) TPC outputs TP15 to TP8 are enabled 1 (NDR15 to NDR8 are transferred to PB 7 to PB 0 ) NDERA--Next Data Enable Register A Bit Initial value Read/Write 7 NDER7 0 R/W 6 NDER6 0 R/W 5 NDER5 0 R/W 4 0 R/W 3 0 R/W H'A3 2 NDER2 0 R/W 1 0 R/W 0 0 TPC NDER4 NDER3 NDER1 NDER0 R/W Next data enable 7 to 0 Bits 7 to 0 NDER7 to NDER0 Description 0 TPC outputs TP 7 to TP0 are disabled (NDR7 to NDR0 are not transferred to PA 7 to PA 0) TPC outputs TP 7 to TP0 are enabled 1 (NDR7 to NDR0 are transferred to PA 7 to PA 0) Rev. 2.0, 03/01, page 749 of 822 NDRB--Next Data Register B * Same trigger for TPC output groups 2 and 3 Address H'FFA4 Bit Initial value Read/Write 7 NDR15 0 R/W 6 NDR14 0 R/W 5 NDR13 0 R/W 4 NDR12 0 R/W 3 NDR11 0 R/W H'A4/H'A6 TPC 2 NDR10 0 R/W 1 NDR9 0 R/W 0 NDR8 0 R/W Store the next output data for TPC output group 3 Store the next output data for TPC output group 2 Address H'FFA6 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- * Different triggers for TPC output groups 2 and 3 Address H'FFA4 Bit Initial value Read/Write 7 NDR15 0 R/W 6 NDR14 0 R/W 5 NDR13 0 R/W 4 NDR12 0 R/W 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Store the next output data for TPC output group 3 Address H'FFA6 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 NDR11 0 R/W 2 NDR10 0 R/W 1 NDR9 0 R/W 0 NDR8 0 R/W Store the next output data for TPC output group 2 Rev. 2.0, 03/01, page 750 of 822 NDRA--Next Data Register A * Same trigger for TPC output groups 0 and 1 Address H'FFA5 Bit Initial value Read/Write 7 NDR7 0 R/W 6 NDR6 0 R/W 5 NDR5 0 R/W 4 NDR4 0 R/W 3 NDR3 0 R/W H'A5/H'A7 TPC 2 NDR2 0 R/W 1 NDR1 0 R/W 0 NDR0 0 R/W Store the next output data for TPC output group 1 Store the next output data for TPC output group 0 Address H'FFA7 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- * Different triggers for TPC output groups 0 and 1 Address H'FFA5 Bit Initial value Read/Write 7 NDR7 0 R/W 6 NDR6 0 R/W 5 NDR5 0 R/W 4 NDR4 0 R/W 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- Store the next output data for TPC output group 1 Address H'FFA7 Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 NDR3 0 R/W 2 NDR2 0 R/W 1 NDR1 0 R/W 0 NDR0 0 R/W Store the next output data for TPC output group 0 Rev. 2.0, 03/01, page 751 of 822 TCSR--Timer Control/Status Register Bit Initial value Read/Write 7 OVF 0 R/(W)* 6 WT/ 0 R/W 5 TME 0 R/W 4 -- 1 -- 3 -- 1 -- H'A8 2 CKS2 0 R/W 1 CKS1 0 R/W WDT 0 CKS0 0 R/W Timer enable 0 Timer disabled * TCNT is initialized to H'00 and halted 1 Timer enabled * TCNT is counting * CPU interrupt requests are enabled Timer mode select 0 Interval timer: requests interval timer interrupts 1 Watchdog timer: generates a reset signal Overflow flag 0 [Clearing condition] Read OVF when OVF = 1, then write 0 in OVF 1 [Setting condition] TCNT changes from H'FF to H'00 Clock select 2 to 0 0 0 0 1 0 1 1 0 1 0 1 0 1 1 o/2 o/32 o/64 o/128 o/256 o/512 o/2048 o/4096 Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 752 of 822 TCNT--Timer Counter H'A9 (read), H'A8 (write) 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W 2 0 R/W 1 0 R/W WDT Bit Initial value Read/Write 7 0 R/W 0 0 R/W Count value RSTCSR--Reset Control/Status Register H'AB (read), H'AA (write) 4 -- 1 -- 3 -- 1 -- 2 -- 1 -- 1 -- 1 -- WDT Bit Initial value Read/Write 7 WRST 0 R/(W)*1 6 -- 0 -- *2 5 -- 1 -- 0 -- 1 -- Watchdog timer reset 0 [Clearing condition] * Reset signal input at RES pin * When WRST= "1", write "0" after reading WRST flag 1 [Setting condition] TCNT overflow generates a reset signal Notes: 1. Only 0 can be written in bit 7, to clear the flag. 2. Bit 6 must not be set to 1; in a write, 0 must always be written in this bit. Rev. 2.0, 03/01, page 753 of 822 RFSHCR--Refresh Control Register Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 M9/M8 0 R/W H'AC 2 RFSHE 0 R/W Refresh controller 1 -- 1 -- 0 RCYCE 0 R/W SRFMD PSRAME DRAME CAS/WE Refresh cycle enable 0 Refresh cycles are disabled 1 Refresh cycles are enabled for area 3 Refresh pin enable 0 Refresh signal output at the RFSH pin is disabled 1 Refresh signal output at the RFSH pin is enabled Address multiplex mode select 0 8-bit column mode 1 9-bit column mode Strobe mode select 0 2 WE mode 1 2 CAS mode PSRAM enable, DRAM enable Bit 6 Bit 5 PSRAME DRAME RAM Interface 0 0 Can be used as an interval timer (DRAM and PSRAM cannot be directly connected) 1 1 0 1 DRAM can be directly connected PSRAM can be directly connected Illegal setting Self-refresh mode 0 DRAM or PSRAM self-refresh is disabled in software standby mode 1 DRAM or PSRAM self-refresh is enabled in software standby mode Rev. 2.0, 03/01, page 754 of 822 RTMCSR--Refresh Timer Control/Status Register Bit Initial value Read/Write 7 CMF 0 R/(W)* 6 CMIE 0 R/W 5 CKS2 0 R/W 4 CKS1 0 R/W 3 CKS0 0 R/W H'AD 2 -- 1 -- Refresh controller 1 -- 1 -- 0 -- 1 -- Clock select 2 to 0 Bit 5 Bit 4 Bit 3 CKS2 CKS1 CKS0 0 0 0 1 0 1 1 0 1 0 1 0 1 1 Counter Clock Source Clock input is disabled o/2 o/8 o/32 o/128 o/512 o/2048 o/4096 Compare match interrupt enable 0 The CMI interrupt requested by CMF is disabled 1 The CMI interrupt requested by CMF is enabled Compare match flag 0 [Clearing condition] Read CMF when CMF = 1, then write 0 in CMF 1 [Setting condition] RTCNT = RTCOR Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 755 of 822 RTCNT--Refresh Timer Counter Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'AE 2 0 R/W Refresh controller 1 0 R/W 0 0 R/W Count value RTCOR--Refresh Time Constant Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'AF 2 1 R/W Refresh controller 1 1 R/W 0 1 R/W Interval at which RTCNT and compare match are set Rev. 2.0, 03/01, page 756 of 822 SMR--Serial Mode Register Bit Initial value Read/Write 7 C/A/GM 0 R/W 6 CHR 0 R/W 5 PE 0 R/W 7 O/ E 0 R/W 3 STOP 0 R/W H'B0 2 MP 0 R/W 1 CKS1 0 R/W SCI0 0 CKS0 0 R/W Multiprocessor mode 0 Multiprocessor function disabled 1 Multiprocessor format selected Stop bit length 0 One stop bit 1 Two stop bits Parity mode 0 Even parity 1 Odd parity Parity enable 0 Parity bit is not added or checked 1 Parity bit is added and checked Character length 0 8-bit data 1 7-bit data Communication mode (when using a serial communication interface) 0 Asynchronous mode 1 Synchronous mode GSM mode (when using a smart card interface) 0 Regular smart card interface operation 1 GSM mode smart card interface operation Clock select 1 and 0 Bit 1 Bit 0 CKS1 CKS0 Clock Source 0 0 o clock 1 o/4 clock 1 o/16 clock 0 o/64 clock 1 Rev. 2.0, 03/01, page 757 of 822 BRR--Bit Rate Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'B1 2 1 R/W 1 1 R/W SCI0 0 1 R/W Serial communication bit rate setting Rev. 2.0, 03/01, page 758 of 822 SCR--Serial Control Register Bit Initial value Read/Write 7 TIE 0 R/W 6 RIE 0 R/W 5 TE 0 R/W 4 RE 0 R/W 3 MPIE 0 R/W H'B2 2 TEIE 0 R/W 1 CKE1 0 R/W 0 SCI0 CKE0 0 R/W Clock enable 1 and 0 Bit 1 Bit 0 CKE1 CKE0 Clock Selection and Output 0 0 Asynchronous mode Internal clock, SCK pin available for generic I/O Synchronous mode Internal clock, SCK pin used for serial clock output Asynchronous mode Internal clock, SCK pin used for clock output 1 Synchronous mode Internal clock, SCK pin used for serial clock output 1 Asynchronous mode External clock, SCK pin used for clock input 0 Synchronous mode External clock, SCK pin used for serial clock input Asynchronous mode External clock, SCK pin used for clock input 1 Synchronous mode External clock, SCK pin used for serial clock input Transmit-end interrupt enable 0 Transmit-end interrupt requests (TEI) are disabled 1 Transmit-end interrupt requests (TEI) are enabled Multiprocessor interrupt enable 0 Multiprocessor interrupts are disabled (normal receive operation) 1 Multiprocessor interrupts are enabled Transmit enable 0 Transmitting is disabled 1 Transmitting is enabled Receive enable 0 Receiving is disabled 1 Receiving is enabled Receive interrupt enable 0 Receive-data-full (RXI) and receive-error (ERI) interrupt requests are disabled 1 Receive-data-full (RXI) and receive-error (ERI) interrupt requests are enabled Transmit interrupt enable 0 Transmit-data-empty interrupt request (TXI) is disabled 1 Transmit-data-empty interrupt request (TXI) is enabled Rev. 2.0, 03/01, page 759 of 822 TDR--Transmit Data Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'B3 2 1 R/W 1 1 R/W SCI0 0 1 R/W Serial transmit data Rev. 2.0, 03/01, page 760 of 822 SSR--Serial Status Register Bit Initial value Read/Write 7 TDRE 1 R/(W)* 6 RDRF 0 R/(W)* 5 0 R/(W)* 4 0 R/(W)* 3 PER 0 R/(W)* H'B4 2 TEND 1 R 1 MPB 0 R SCI0 0 MPBT 0 R/W ORER FER/ERS Multiprocessor bit 0 1 Multiprocessor bit value in receive data is 0 Multiprocessor bit value in receive data is 1 Multiprocessor bit transfer 0 1 Multiprocessor bit value in transmit data is 0 Multiprocessor bit value in transmit data is 1 Parity error 0 [Clearing conditions] Reset or transition to standby mode. Read PER when PER = 1, then write 0 in PER. [Setting condition] Parity error: (parity of receive data does not match parity setting O/E bit in SMR) Transmit end 0 [Clearing conditions] Read TDRE when TDRE = 1, then write 0 in TDRE. The DMAC writes data in TDR. [Setting conditions] Reset or transition to standby mode. TE is cleared to 0 in SCR and FER/ERS is cleared to 0. TDRE is 1 when last bit of 1-byte serial character is transmitted. 1 1 Error signal status (for smart card interface) Framing error (for SCI0) 0 [Clearing conditions] Reset or transition to standby mode. Read FER when FER = 1, then write 0 in FER. [Setting condition] Framing error (stop bit is 0) 0 [Clearing conditions] Reset or transition to standby mode. Read ERS when ERS = 1, then write 0 in ERS. [Setting condition] A low error signal is received. 1 1 Overrun error Receive data register full 0 [Clearing conditions] Reset or transition to standby mode. Read RDRF when RDRF = 1, then write 0 in RDRF. The DMAC reads data from RDR. [Setting condition] Serial data is received normally and transferred from RSR to RDR 0 [Clearing conditions] Reset or transition to standby mode. Read ORER when ORER = 1, then write 0 in ORER. [Setting condition] Overrun error (reception of next serial data ends when RDRF = 1) 1 1 Transmit data register empty 0 [Clearing conditions] Read TDRE when TDRE = 1, then write 0 in TDRE. The DMAC writes data in TDR. [Setting conditions] Reset or transition to standby mode. TE is 0 in SCR Data is transferred from TDR to TSR, enabling new data to be written in TDR. 1 Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 761 of 822 RDR--Receive Data Register Bit Initial value Read/Write 7 0 R 6 0 R 5 0 R 4 0 R 3 0 R H'B5 2 0 R 1 0 R SCI0 0 0 R Serial receive data SCMR--Smart Card Mode Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 SDIR 0 R/W H'B6 2 SINV 0 R/W 1 -- 1 -- SCI0 0 SMIF 0 R/W Smart card interface mode select 0 Smart card interface function is disabled 1 Smart card interface function is enabled Smart card data invert 0 Unmodified TDR contents are transmitted Received data is stored unmodified in RDR (Initial value) (Initial value) 1 Inverted TDR contents are transmitted Received data are inverted before storage in RDR Smart card data transfer direction 0 TDR contents are transmitted LSB-first (Initial value) Received data is stored LSB-first in RDR 1 TDR contents are transmitted MSB-first Received data is stored MSB-first in RDR Rev. 2.0, 03/01, page 762 of 822 SMR--Serial Mode Register Bit Initial value Read/Write 7 C/ 0 R/W 6 CHR 0 R/W 5 PE 0 R/W 4 O/ 0 R/W 3 STOP 0 R/W H'B8 2 MP 0 R/W 1 CKS1 0 R/W SCI1 0 CKS0 0 R/W Note: Bit functions are the same as for SCI0. BRR--Bit Rate Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'B9 2 1 R/W 1 1 R/W SCI1 0 1 R/W Note: Bit functions are the same as for SCI0. SCR--Serial Control Register Bit Initial value Read/Write 7 TIE 0 R/W 6 RIE 0 R/W 5 TE 0 R/W 4 RE 0 R/W 3 MPIE 0 R/W H'BA 2 TEIE 0 R/W 1 CKE1 0 R/W SCI1 0 CKE0 0 R/W Note: Bit functions are the same as for SCI0. Rev. 2.0, 03/01, page 763 of 822 TDR--Transmit Data Register Bit Initial value Read/Write 7 1 R/W 6 1 R/W 5 1 R/W 4 1 R/W 3 1 R/W H'BB 2 1 R/W 1 1 R/W SCI1 0 1 R/W Note: Bit functions are the same as for SCI0. SSR--Serial Status Register Bit Initial value Read/Write 7 TDRE 1 R/(W)* 6 RDRF 0 R/(W)* 5 ORER 0 R/(W)* 4 FER 0 R/(W)* 3 PER 0 R/(W)* H'BC 2 TEND 1 R 1 MPB 0 R SCI1 0 MPBT 0 R/W Notes: Bit functions are the same as for SCI0. * Only 0 can be written, to clear the flag. RDR--Receive Data Register Bit Initial value Read/Write 7 0 R 6 0 R 5 0 R 4 0 R 3 0 R H'BD 2 0 R 1 0 R SCI1 0 0 R Note: Bit functions are the same as for SCI0. Rev. 2.0, 03/01, page 764 of 822 P1DDR--Port 1 Data Direction Register Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 1 -- 0 W 6 1 -- 0 W 5 1 -- 0 W 4 1 -- 0 W 3 1 -- 0 W H'C0 2 1 -- 0 W 1 1 -- 0 W Port 1 0 1 -- 0 W P17 DDR P16 DDR P15 DDR P14 DDR P13 DDR P12 DDR P11 DDR P10 DDR Port 1 input/output select 0 Generic input pin 1 Generic output pin P2DDR--Port 2 Data Direction Register Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 1 -- 0 W 6 1 -- 0 W 5 1 -- 0 W 4 1 -- 0 W 3 1 -- 0 W H'C1 2 1 -- 0 W 1 1 -- 0 W Port 2 0 1 -- 0 W P27 DDR P26 DDR P25 DDR P24 DDR P23 DDR P22 DDR P21 DDR P20 DDR Port 2 input/output select 0 Generic input pin 1 Generic output pin P1DR--Port 1 Data Register Bit Initial value Read/Write 7 P17 0 R/W 6 P16 0 R/W 5 P15 0 R/W 4 P14 0 R/W 3 P13 0 R/W H'C2 2 P12 0 R/W 1 P11 0 R/W Port 1 0 P10 0 R/W Data for port 1 pins Rev. 2.0, 03/01, page 765 of 822 P2DR--Port 2 Data Register Bit Initial value Read/Write 7 P2 7 0 R/W 6 P2 6 0 R/W 5 P2 5 0 R/W 4 P2 4 0 R/W 3 P2 3 0 R/W H'C3 2 P2 2 0 R/W 1 P2 1 0 R/W Port 2 0 P2 0 0 R/W Data for port 2 pins P3DDR--Port 3 Data Direction Register Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W H'C4 2 0 W 1 0 W Port 3 0 0 W P3 7 DDR P3 6 DDR P3 5 DDR P3 4 DDR P3 3 DDR P3 2 DDR P3 1 DDR P3 0 DDR Port 3 input/output select 0 Generic input pin 1 Generic output pin P4DDR--Port 4 Data Direction Register Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W H'C5 2 0 W 1 0 W Port 4 0 0 W P4 7 DDR P4 6 DDR P4 5 DDR P4 4 DDR P4 3 DDR P4 2 DDR P4 1 DDR P4 0 DDR Port 4 input/output select 0 Generic input pin 1 Generic output pin Rev. 2.0, 03/01, page 766 of 822 P3DR--Port 3 Data Register Bit Initial value Read/Write 7 P3 7 0 R/W 6 P3 6 0 R/W 5 P3 5 0 R/W 4 P3 4 0 R/W 3 P3 3 0 R/W H'C6 2 P3 2 0 R/W 1 P3 1 0 R/W Port 3 0 P3 0 0 R/W Data for port 3 pins P4DR--Port 4 Data Register Bit Initial value Read/Write 7 P4 7 0 R/W 6 P4 6 0 R/W 5 P4 5 0 R/W 4 P4 4 0 R/W 3 P4 3 0 R/W H'C7 2 P4 2 0 R/W 1 P4 1 0 R/W Port 4 0 P4 0 0 R/W Data for port 4 pins P5DDR--Port 5 Data Direction Register Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 -- 1 -- 1 -- 6 -- 1 -- 1 -- 5 -- 1 -- 1 -- 4 -- 1 -- 1 -- 3 1 -- 0 W H'C8 2 1 -- 0 W 1 1 -- 0 W Port 5 0 1 -- 0 W P5 3 DDR P5 2 DDR P5 1 DDR P5 0 DDR Port 5 input/output select 0 Generic input pin 1 Generic output pin Rev. 2.0, 03/01, page 767 of 822 P6DDR--Port 6 Data Direction Register Bit Initial value Read/Write 7 -- 1 -- 6 0 W 5 0 W 4 0 W 3 0 W H'C9 2 0 W 1 0 W Port 6 0 0 W P6 6 DDR P6 5 DDR P6 4 DDR P6 3 DDR P6 2 DDR P6 1 DDR P6 0 DDR Port 6 input/output select 0 Generic input pin 1 Generic output pin P5DR--Port 5 Data Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 P5 3 0 R/W H'CA 2 P5 2 0 R/W 1 P5 1 0 R/W Port 5 0 P5 0 0 R/W Data for port 5 pins P6DR--Port 6 Data Register Bit Initial value Read/Write 7 -- 1 -- 6 P6 6 0 R/W 5 P6 5 0 R/W 4 P6 4 0 R/W 3 P6 3 0 R/W H'CB 2 P6 2 0 R/W 1 P6 1 0 R/W Port 6 0 P6 0 0 R/W Data for port 6 pins Rev. 2.0, 03/01, page 768 of 822 P8DDR--Port 8 Data Direction Register Bit Modes Initial value 1 to 4 Read/Write Modes Initial value 5 to 7 Read/Write 7 -- 1 -- 1 -- 6 -- 1 -- 1 -- 5 -- 1 -- 1 -- 4 1 W 0 W 3 0 W 0 W H'CD 2 0 W 0 W 1 0 W 0 W Port 8 0 0 W 0 W P8 4 DDR P8 3 DDR P8 2 DDR P8 1 DDR P8 0 DDR Port 8 input/output select 0 Generic input pin 1 CS output pin Port 8 input/output select 0 Generic input pin 1 Generic output pin P7DR--Port 7 Data Register Bit Initial value Read/Write 7 P77 --* R 6 P76 --* R 5 P75 --* R 4 P74 --* R 3 P73 --* R H'CE 2 P72 --* R 1 P71 --* R Port 7 0 P70 --* R Read the pin levels for port 7 Note: * Determined by pins P7 7 to P7 0 . P8DR--Port 8 Data Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 P8 4 0 R/W 3 P8 3 0 R/W H'CF 2 P8 2 0 R/W 1 P8 1 0 R/W Port 8 0 P8 0 0 R/W Data for port 8 pins Rev. 2.0, 03/01, page 769 of 822 P9DDR--Port 9 Data Direction Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 0 W 4 0 W 3 0 W H'D0 2 0 W 1 0 W Port 9 0 0 W P9 5 DDR P9 4 DDR P9 3 DDR P9 2 DDR P9 1 DDR P9 0 DDR Port 9 input/output select 0 Generic input pin 1 Generic output pin PADDR--Port A Data Direction Register Bit Modes Initial value 3, 4, 6 Read/Write Modes Initial value 1, 2, Read/Write 5, 7 7 1 -- 0 W 6 0 W 0 W 5 0 W 0 W 4 0 W 0 W 3 0 W 0 W H'D1 2 0 W 0 W 1 0 W 0 W Port A 0 0 W 0 W PA 7 DDR PA 6 DDR PA 5 DDR PA 4 DDR PA 3 DDR PA 2 DDR PA 1 DDR PA 0 DDR Port A input/output select 0 Generic input pin 1 Generic output pin P9DR--Port 9 Data Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 P9 5 0 R/W 4 P9 4 0 R/W 3 P9 3 0 R/W H'D2 2 P9 2 0 R/W 1 P9 1 0 R/W Port 9 0 P9 0 0 R/W Data for port 9 pins Rev. 2.0, 03/01, page 770 of 822 PADR--Port A Data Register Bit Initial value Read/Write 7 PA 7 0 R/W 6 PA 6 0 R/W 5 PA 5 0 R/W 4 PA 4 0 R/W 3 PA 3 0 R/W H'D3 2 PA 2 0 R/W 1 PA 1 0 R/W Port A 0 PA 0 0 R/W Data for port A pins PBDDR--Port B Data Direction Register Bit Initial value Read/Write 7 0 W 6 0 W 5 0 W 4 0 W 3 0 W H'D4 2 0 W 1 0 W Port B 0 0 W PB7 DDR PB6 DDR PB5 DDR PB4 DDR PB3 DDR PB2 DDR PB1 DDR PB0 DDR Port B input/output select 0 Generic input pin 1 Generic output pin PBDR--Port B Data Register Bit Initial value Read/Write 7 PB 7 0 R/W 6 PB 6 0 R/W 5 PB 5 0 R/W 4 PB 4 0 R/W 3 PB 3 0 R/W H'D6 2 PB 2 0 R/W 1 PB 1 0 R/W Port B 0 PB 0 0 R/W Data for port B pins Rev. 2.0, 03/01, page 771 of 822 P2PCR--Port 2 Input Pull-Up MOS Control Register Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'D8 2 0 R/W 1 0 R/W Port 2 0 0 R/W P2 7 PCR P2 6 PCR P2 5 PCR P2 4 PCR P2 3 PCR P2 2 PCR P2 1 PCR P2 0 PCR Port 2 input pull-up MOS control 7 to 0 0 Input pull-up transistor is off 1 Input pull-up transistor is on Note: Valid when the corresponding P2DDR bit is cleared to 0 (designating generic input). P4PCR--Port 4 Input Pull-Up MOS Control Register Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'DA 2 0 R/W 1 0 R/W Port 4 0 0 R/W P4 7 PCR P4 6 PCR P4 5 PCR P4 4 PCR P4 3 PCR P4 2 PCR P4 1 PCR P4 0 PCR Port 4 input pull-up MOS control 7 to 0 0 Input pull-up transistor is off 1 Input pull-up transistor is on Note: Valid when the corresponding P4DDR bit is cleared to 0 (designating generic input). Rev. 2.0, 03/01, page 772 of 822 P5PCR--Port 5 Input Pull-Up MOS Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 0 R/W H'DB 2 0 R/W 1 0 R/W Port 5 0 0 R/W P5 3 PCR P5 2 PCR P5 1 PCR P5 0 PCR Port 5 input pull-up MOS control 3 to 0 0 Input pull-up transistor is off 1 Input pull-up transistor is on Note: Valid when the corresponding P5DDR bit is cleared to 0 (designating generic input). DADR0--D/A Data Register 0 Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'DC 2 0 R/W 1 0 R/W 0 0 D/A R/W D/A conversion data DADR1--D/A Data Register 1 Bit Initial value Read/Write 7 0 R/W 6 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'DD 2 0 R/W 1 0 R/W 0 0 D/A R/W D/A conversion data Rev. 2.0, 03/01, page 773 of 822 DACR--D/A Control Register Bit Initial value Read/Write 7 DAOE1 0 R/W 6 DAOE0 0 R/W 5 DAE 0 R/W 4 -- 1 -- 3 -- 1 -- H'DE 2 -- 1 -- 1 -- 1 -- 0 -- 1 -- D/A D/A enable Bit 7 Bit 6 Bit 5 DAOE1 DAOE0 DAE 0 -- 0 1 0 1 0 1 -- 1 0 1 Description D/A conversion is disabled in channels 0 and 1 D/A conversion is enabled in channel 0 D/A conversion is disabled in channel 1 D/A conversion is enabled in channels 0 and 1 D/A conversion is disabled in channel 0 D/A conversion is enabled in channel 1 D/A conversion is enabled in channels 0 and 1 D/A conversion is enabled in channels 0 and 1 D/A output enable 0 0 DA0 analog output is disabled 1 Channel-0 D/A conversion and DA0 analog output are enabled D/A output enable 1 0 DA1 analog output is disabled 1 Channel-1 D/A conversion and DA1 analog output are enabled ADDRA H/L--A/D Data Register A H/L Bit Initial value Read/Write 15 0 R 14 0 R 13 0 R 12 0 R 11 0 R 10 0 R 9 0 R 8 0 R 7 0 R 6 0 R H'E0, H'E1 5 0 R 4 -- 0 R 3 -- 0 R 2 -- 0 R 1 -- 0 R A/D 0 -- 0 R AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 -- ADDRAH A/D conversion data 10-bit data giving an A/D conversion result ADDRAL Rev. 2.0, 03/01, page 774 of 822 ADDRB H/L--A/D Data Register B H/L Bit Initial value Read/Write 15 0 R 14 0 R 13 0 R 12 0 R 11 0 R 10 0 R 9 0 R 8 0 R 7 0 R 6 0 R H'E2, H'E3 5 0 R 4 -- 0 R 3 -- 0 R 2 -- 0 R 1 -- 0 R A/D 0 -- 0 R AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 -- ADDRBH A/D conversion data 10-bit data giving an A/D conversion result ADDRBL ADDRC H/L--A/D Data Register C H/L Bit Initial value Read/Write 15 0 R 14 0 R 13 0 R 12 0 R 11 0 R 10 0 R 9 0 R 8 0 R 7 0 R 6 0 R H'E4, H'E5 5 0 R 4 -- 0 R 3 -- 0 R 2 -- 0 R 1 -- 0 R A/D 0 -- 0 R AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 -- ADDRCH A/D conversion data 10-bit data giving an A/D conversion result ADDRCL ADDRD H/L--A/D Data Register D H/L Bit Initial value Read/Write 15 0 R 14 0 R 13 0 R 12 0 R 11 0 R 10 0 R 9 0 R 8 0 R 7 0 R 6 0 R H'E6, H'E7 5 0 R 4 -- 0 R 3 -- 0 R 2 -- 0 R 1 -- 0 R A/D 0 -- 0 R AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 -- ADDRDH A/D conversion data 10-bit data giving an A/D conversion result ADDRDL Rev. 2.0, 03/01, page 775 of 822 ADCSR--A/D Control/Status Register Bit Initial value Read/Write 7 ADF 0 R/(W)* 6 ADIE 0 R/W 5 ADST 0 R/W 4 SCAN 0 R/W 3 CKS 0 R/W H'E8 2 CH2 0 R/W 1 CH1 0 R/W 0 A/D CH0 0 R/W Clock select 0 Conversion time = 266 states (maximum) 1 Conversion time = 134 states (maximum) Channel select 2 to 0 Channel Group Selection Selection CH2 CH1 CH0 0 0 0 1 0 1 1 0 1 0 1 0 1 1 Scan mode 0 Single mode 1 Scan mode Description Single Mode Scan Mode AN 0 AN 0 AN 1 AN 0, AN 1 AN 2 AN 0 to AN 2 AN 3 AN 0 to AN 3 AN 4 AN 4 AN 5 AN 4, AN 5 AN 6 AN 4 to AN 6 AN 7 AN 4 to AN 7 A/D start 0 A/D conversion is stopped 1 Single mode: A/D conversion starts; ADST is automatically cleared to 0 when conversion ends Scan mode: A/D conversion starts and continues, cycling among the selected channels, until ADST is cleared to 0 by software, by a reset, or by a transition to standby mode A/D interrupt enable 0 A/D end interrupt request is disabled 1 A/D end interrupt request is enabled A/D end flag 0 [Clearing condition] Read ADF while ADF = 1, then write 0 in ADF 1 [Setting conditions] Single mode: A/D conversion ends Scan mode: A/D conversion ends in all selected channels Note: * Only 0 can be written, to clear flag. Rev. 2.0, 03/01, page 776 of 822 ADCR--A/D Control Register Bit Initial value Read/Write 7 TRGE 0 R/W 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 -- 1 -- H'E9 2 -- 1 -- 1 -- 1 -- 0 -- 0 A/D --* Trigger enable 0 A/D conversion cannot be externally triggered 1 A/D conversion starts at the fall of the external trigger signal (ADTRG ) Note: * Bit 0 must not be set to 1; in a write, 0 must always be written in this bit. ABWCR--Bus Width Control Register Bit 7 ABW7 Initial Mode 1, 3, 5, 6 1 value Mode 2, 4, 7 0 Read/Write R/W 6 ABW6 1 0 R/W 5 ABW5 1 0 R/W 4 ABW4 1 0 R/W 3 ABW3 1 0 R/W H'EC 2 ABW2 1 0 R/W Bus controller 1 ABW1 1 0 R/W 0 ABW0 1 0 R/W Area 7 to 0 bus width control Bits 7 to 0 ABW7 to ABW0 Bus Width of Access Area 0 Areas 7 to 0 are 16-bit access areas Areas 7 to 0 are 8-bit access areas 1 ASTCR--Access State Control Register Bit Initial value Read/Write 7 AST7 1 R/W 6 AST6 1 R/W 5 AST5 1 R/W 4 AST4 1 R/W 3 AST3 1 R/W H'ED 2 AST2 1 R/W Bus controller 1 AST1 1 R/W 0 AST0 1 R/W Area 7 to 0 access state control Bits 7 to 0 AST7 to AST0 Number of States in Access Cycle 0 Areas 7 to 0 are two-state access areas Areas 7 to 0 are three-state access areas 1 Rev. 2.0, 03/01, page 777 of 822 WCR--Wait Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 1 -- 4 -- 1 -- 3 WMS1 0 R/W H'EE 2 WMS0 0 R/W Bus controller 1 WC1 1 R/W 0 WC0 1 R/W Wait mode select 1 and 0 Bit 3 Bit 2 WMS1 WMS0 Wait Mode 0 0 Programmable wait mode 1 1 0 1 No wait states inserted by wait-state controller Pin wait mode 1 Pin auto-wait mode Wait count 1 and 0 Bit 1 Bit 0 WC1 WC0 Number of Wait States 0 0 No wait states inserted by wait-state controller 1 1 0 1 1 state inserted 2 states inserted 3 states inserted WCER--Wait-State Controller Enable Register Bit Initial value Read/Write 7 WCE7 1 R/W 6 WCE6 1 R/W 5 WCE5 1 R/W 4 WCE4 1 R/W 3 WCE3 1 R/W H'EF 2 WCE2 1 R/W Bus controller 1 WCE1 1 R/W 0 WCE0 1 R/W Wait-state controller enable 7 to 0 0 Wait-state control is disabled (pin wait mode 0) 1 Wait-state control is enabled Rev. 2.0, 03/01, page 778 of 822 MDCR--Mode Control Register Bit Initial value Read/Write 7 -- 1 -- 6 -- 1 -- 5 -- 0 -- 4 -- 0 -- 3 -- 0 -- H'F1 2 MDS2 --* R System control 1 MDS1 --* R 0 MDS0 --* R Mode select 2 to 0 Bit 2 Bit 1 Bit 0 MD2 MD1 MD0 0 0 0 1 0 1 1 0 1 0 1 0 1 1 Operating mode -- Mode 1 Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Note: * Determined by the state of the mode pins (MD 2 to MD0 ). Rev. 2.0, 03/01, page 779 of 822 SYSCR--System Control Register Bit Initial value Read/Write 7 SSBY 0 R/W 6 STS2 0 R/W 5 STS1 0 R/W 4 STS0 0 R/W 3 UE 1 R/W H'F2 2 NMIEG 0 R/W System control 1 -- 1 -- 0 RAME 1 R/W RAM enable 0 On-chip RAM is disabled 1 On-chip RAM is enabled NMI edge select 0 An interrupt is requested at the falling edge of NMI 1 An interrupt is requested at the rising edge of NMI User bit enable 0 CCR bit 6 (UI) is used as an interrupt mask bit 1 CCR bit 6 (UI) is used as a user bit Standby timer select 2 to 0 Bit 6 Bit 5 Bit 4 STS2 STS1 STS0 Standby Timer 0 0 0 Waiting time = 8,192 states 1 Waiting time = 16,384 states 0 Waiting time = 32,768 states 1 1 Waiting time = 65,536 states Waiting time = 131,072 states 0 0 1 Waiting time = 1,024 states 1 1 -- Illegal setting Software standby 0 SLEEP instruction causes transition to sleep mode 1 SLEEP instruction causes transition to software standby mode Rev. 2.0, 03/01, page 780 of 822 BRCR--Bus Release Control Register Bit 7 6 A22E 1 -- 1 R/W 5 A21E 1 -- 1 R/W 4 -- 1 -- 1 -- 3 -- 1 -- 1 -- H'F3 2 -- 1 -- 1 -- Bus controller 1 -- 1 -- 1 -- 0 BRLE 0 R/W 0 R/W A23E Modes Initial value 1 1, 2, Read/Write -- 5, 7 1 Modes Initial value 3, 4, 6 Read/Write R/W Bus release enable 0 The bus cannot be released to an external device 1 The bus can be released to an external device Address 23 to 21 enable 0 Address output 1 Other input/output ISCR--IRQ Sense Control Register Bit Initial value Read/Write 7 -- 0 R/W 6 -- 0 R/W 5 0 R/W 4 0 R/W 3 0 R/W H'F4 2 0 R/W Interrupt controller 1 0 R/W 0 0 R/W IRQ5SC IRQ4SC IRQ3SC IRQ2SC IRQ1SC IRQ0SC IRQ 5 to IRQ 0 sense control 0 Interrupts are requested when IRQ 5 to IRQ 0 inputs are low 1 Interrupts are requested by falling-edge input at IRQ 5 to IRQ0 IER--IRQ Enable Register Bit Initial value Read/Write 7 -- 0 R/(W) 6 -- 0 R/(W) 5 IRQ5E 0 R/(W) 4 IRQ4E 0 R/(W) 3 IRQ3E 0 R/(W) H'F5 2 IRQ2E 0 R/(W) Interrupt controller 1 IRQ1E 0 R/(W) 0 IRQ0E 0 R/(W) IRQ5 to IRQ 0 enable 0 IRQ 5 to IRQ 0 interrupts are disabled 1 IRQ 5 to IRQ 0 interrupts are enabled Rev. 2.0, 03/01, page 781 of 822 ISR--IRQ Status Register Bit Initial value Read/Write 7 -- 0 -- 6 -- 0 -- 5 IRQ5F 0 R/(W)* 4 IRQ4F 0 R/(W)* 3 IRQ3F 0 R/(W)* H'F6 2 IRQ2F 0 R/(W)* Interrupt controller 1 IRQ1F 0 R/(W)* 0 IRQ0F 0 R/(W)* IRQ 5 to IRQ 0 flags Bits 5 to 0 IRQ5F to IRQ0F 0 Setting and Clearing Conditions [Clearing conditions] Read IRQnF when IRQnF = 1, then write 0 in IRQnF. IRQnSC = 0, input is high, and interrupt exception handling is carried out. IRQnSC = 1 and IRQn interrupt exception handling is carried out. [Setting conditions] IRQnSC = 0 and input is low. IRQnSC = 1 and a falling edge is generated in the 1 input. (n = 5 to 0) Note: * Only 0 can be written, to clear the flag. Rev. 2.0, 03/01, page 782 of 822 IPRA--Interrupt Priority Register A Bit Initial value Read/Write 7 IPRA7 0 R/W 6 IPRA6 0 R/W 5 IPRA5 0 R/W 4 IPRA4 0 R/W 3 IPRA3 0 R/W H'F8 2 IPRA2 0 R/W Interrupt controller 1 IPRA1 0 R/W 0 IPRA0 0 R/W Priority level A7 to A0 0 Priority level 0 (low priority) 1 Priority level 1 (high priority) * Interrupt sources controlled by each bit Bit 7: IPRA7 Interrupt source IRQ0 Bit 6: IPRA6 IRQ1 Bit 5: IPRA5 IRQ2, IRQ3 Bit 4: IPRA4 IRQ4, IRQ5 Bit 3: IPRA3 Bit 2: IPRA2 Bit 1: IPRA1 ITU channel 1 Bit 0: IPRA0 ITU channel 2 WDT, ITU Refresh channel Controller 0 IPRB--Interrupt Priority Register B Bit Initial value Read/Write 7 IPRB7 0 R/W 6 IPRB6 0 R/W 5 IPRB5 0 R/W 4 -- 0 R/W 3 IPRB3 0 R/W H'F9 2 IPRB2 0 R/W Interrupt controller 1 IPRB1 0 R/W 0 -- 0 R/W Priority level B7 to B5, B3 to B 1 0 Priority level 0 (low priority) 1 Priority level 1 (high priority) * Interrupt sources controlled by each bit Bit 7: IPRB7 Interrupt source ITU channel 3 Bit 6: IPRB6 ITU channel 4 Bit 5: IPRB5 DMAC Bit 4: -- -- Bit 3: IPRB3 SCI channel 0 Bit 2: IPRB2 SCI channel 1 Bit 1: IPRB1 Bit 0: -- A/D -- converter Rev. 2.0, 03/01, page 783 of 822 Appendix C I/O Port Block Diagrams C.1 Port 1 Block Diagram Software standby Mode 7 Hardware standby External bus released Mode 1 to 4 Internal data bus (upper) Reset R Q P1 n DDR C WP1D Reset D Mode 7 R P1 n Q P1 nDR C WP1 D Mode 1 to 6 RP1 WP1D: Write to P1DDR WP1: Write to port 1 RP1: Read port 1 n = 0 to 7 Figure C.1 Port 1 Block Diagram Rev. 2.0, 03/01, page 784 of 822 Internal address bus C.2 Port 2 Block Diagram Reset Internal data bus (upper) R Q Software standby Mode 7 Hardware standby External bus released P2 n PCR C RP2P WP2P Reset Mode 1 to 4 R Q P2n DDR C WP2D Reset Mode 7 R Q P2 nDR C WP2 D D D P2 n Mode 1 to 6 RP2 WP2P: Write to P2PCR RP2P: Read P2PCR WP2D: Write to P2DDR WP2: Write to port 2 RP2: Read port 2 n = 0 to 7 Figure C.2 Port 2 Block Diagram Rev. 2.0, 03/01, page 785 of 822 Internal address bus C.3 Port 3 Block Diagram Internal data bus (upper) Reset Hardware standby External bus released R Mode 7 Q Write to external address P3 n DDR C WP3D Reset R Mode 7 P3 n Q P3 nDR C WP3 D D Mode 1 to 6 RP3 Read external address WP3D: Write to P3DDR WP3: Write to port 3 RP3: Read port 3 n = 0 to 7 Figure C.3 Port 3 Block Diagram Rev. 2.0, 03/01, page 786 of 822 Internal data bus (lower) C.4 Port 4 Block Diagram 8-bit bus 16-bit bus mode mode Mode 7 Mode 1 to 6 Reset Internal data bus (upper) Internal data bus (lower) R Q P4 n PCR RP4P C WP4P Reset R Write to external address Q P4 n DDR C WP4D Reset R P4 n Q P4n DR C WP4 D D D RP4 Read external address WP4P: Write to P4PCR RP4P: Read P4PCR WP4D: Write to P4DDR WP4: Write to port 4 RP4: Read port 4 n = 0 to 7 Figure C.4 Port 4 Block Diagram Rev. 2.0, 03/01, page 787 of 822 C.5 Port 5 Block Diagram Reset Q Software standby Mode 7 RP5P Hardware standby External bus released P5 n PCR C WP5P Mode 1 to 4 D Internal data bus (upper) R Reset R Q P5 n DDR C WP5D Reset R Q P5n DR C D D Mode 7 P5 n Mode 1 to 6 WP5 RP5 WP5P: Write to P5PCR RP5P: Read P5PCR WP5D: Write to P5DDR WP5: Write to port 5 RP5: Read port 5 n = 0 to 3 Figure C.5 Port 5 Block Diagram Rev. 2.0, 03/01, page 788 of 822 Internal address bus C.6 Port 6 Block Diagrams Reset Internal data bus R Q P60 DDR C Mode 7 WP6D Reset R P6 0 Q P60 DR C WP6 D D Bus controller WAIT input enable RP6 Bus controller WAIT input WP6D: Write to P6DDR WP6: Write to port 6 RP6: Read port 6 Figure C.6 (a) Port 6 Block Diagram (Pin P60) Rev. 2.0, 03/01, page 789 of 822 Reset Internal data bus R Q P6 1 DDR C Mode 7 WP6D Reset R P6 1 Q P61 DR C WP6 D D Bus controller Bus release enable RP6 BREQ input WP6D: Write to P6DDR WP6: Write to port 6 RP6: Read port 6 Figure C.6 (b) Port 6 Block Diagram (Pin P61) Rev. 2.0, 03/01, page 790 of 822 Reset R Q P6 2 DDR C WP6D Reset R P6 2 Q P62 DR C Mode 7 WP6 D Bus controller Bus release enable BACK output D Internal data bus RP6 WP6D: Write to P6DDR WP6: Write to port 6 RP6: Read port 6 Figure C.6 (c) Port 6 Block Diagram (Pin P62) Rev. 2.0, 03/01, page 791 of 822 Software standby Mode 7 Hardware standby External bus released Mode 7 Reset R Q P6 n DDR C WP6D Reset R D Internal data bus Mode 7 P6 n Q Mode 1 to 6 P6 nDR C WP6 AS output RD output HWR output LWR output D RP6 WP6D: Write to P6DDR WP6: Write to port 6 RP6: Read port 6 n = 6 to 3 Figure C.6 (d) Port 6 Block Diagram (Pins P66 to P63) Rev. 2.0, 03/01, page 792 of 822 C.7 Port 7 Block Diagrams RP7 P7n Internal data bus A/D converter Input enable Analog input RP7: Read port 7 n = 0 to 5 Figure C.7 (a) Port 7 Block Diagram (Pins P70 to P75) RP7 P7n Internal data bus A/D converter Input enable Analog input D/A converter Output enable Analog output RP7: Read port 7 n = 6 or 7 Figure C.7 (b) Port 7 Block Diagram (Pins P76, P77) Rev. 2.0, 03/01, page 793 of 822 C.8 Port 8 Block Diagrams Reset R Q P8 0 DDR C WP8D Reset R D Internal data bus P8 0 Q P80 DR C Mode 7 WP8 D Refresh controller Output enable RFSH output RP8 Interrupt controller WP8D: Write to P8DDR WP8: Write to port 8 RP8: Read port 8 IRQ 0 input Figure C.8 (a) Port 8 Block Diagram (Pin P80) Rev. 2.0, 03/01, page 794 of 822 Reset R Q P8 n DDR C WP8 Reset Mode 7 P8 n Mode 1 to 6 Q P8n DR C WP8 R D D Internal data bus Bus controller CS 1 CS 2 CS 3 output RP8 Interrupt controller IRQ 1 IRQ 2 IRQ 3 input WP8D Write to P8DDR WP8: Write to port 8 RP8: Read port 8 n = 1 to 3 Figure C.8 (b) Port 8 Block Diagram (Pins P81 to P83) Rev. 2.0, 03/01, page 795 of 822 Reset Mode 1 to 4 S Q R D Internal data bus P8 4 DDR C WP8D Reset R Mode 6/7 P8 4 Mode 1 to 5 Q P84 DR C WP8 D Bus controller CS 0 output RP8 WP8D: Write to P8DDR WP8: Write to port 8 RP8: Read port 8 Figure C.8 (c) Port 8 Block Diagram (Pin P84) Rev. 2.0, 03/01, page 796 of 822 C.9 Port 9 Block Diagrams Reset R Q P9 0 DDR C WP9D Reset R P9 0 Q P90 DR C WP9 D SCI0 Output enable Serial transmit data Guard time RP9 D Internal data bus WP9D: Write to P9DDR WP9: Write to port 9 RP9: Read port 9 Figure C.9 (a) Port 9 Block Diagram (Pin P90) Rev. 2.0, 03/01, page 797 of 822 Reset R Q P9 1 DDR C WP9D Reset R P9 1 Q P91 DR C WP9 D SCI1 Output enable Serial transmit data D Internal data bus RP9 WP9D: Write to P9DDR WP9: Write to port 9 RP9: Read port 9 Figure C.9 (b) Port 9 Block Diagram (Pin P91) Rev. 2.0, 03/01, page 798 of 822 Reset R Q P9 n DDR C WP9D Reset R P9 n Q P9n DR C WP9 D D Internal data bus SCI Input enable RP9 Serial receive data WP9D: Write to P9DDR WP9: Write to port 9 RP9: Read port 9 n = 2 or 3 Figure C.9 (c) Port 9 Block Diagram (Pins P92, P93) Rev. 2.0, 03/01, page 799 of 822 Reset R Q P9 n DDR C WP9D Reset R P9 n Q P9n DR C WP9 Clock output enable Clock output D D Internal data bus SCI Clock input enable RP9 Clock input WP9D: Write to P9DDR WP9: Write to port 9 RP9: Read port 9 n = 4 or 5 Interrupt controller IRQ 4 IRQ 5 input Figure C.9 (d) Port 9 Block Diagram (Pins P94, P95) Rev. 2.0, 03/01, page 800 of 822 C.10 Port A Block Diagrams Reset R Q PA n DDR C WPAD Reset R D Internal data bus TPC PAn Q PA n DR C D TPC output enable Next data WPA Output trigger DMA controller Output enable Transfer end output ITU RPA Counter clock input WPAD: Write to PADDR WPA: Write to port A RPA: Read port A n = 0 or 1 Figure C.10 (a) Port A Block Diagram (Pins PA0, PA1) Rev. 2.0, 03/01, page 801 of 822 Reset R Q PA n DDR C WPAD Reset R PAn Q PAn DR C D D Internal data bus TPC TPC output enable Next data WPA Output trigger ITU Output enable Compare match output RPA Input capture Counter clock input WPAD: Write to PADDR WPA: Write to port A RPA: Read port A n = 2 or 3 Figure C.10 (b) Port A Block Diagram (Pins PA2, PA3) Rev. 2.0, 03/01, page 802 of 822 Software standby External bus released Hardware standby Bus controller Chip select enable Reset R Q PAnDDR C WPAD Reset PAn Q PAnDR C R D Next data TPC output enable D Internal address bus Internal data bus Address output enable CS4 CS5 CS6 output TPC WPA Output trigger ITU Output enable Compare match output PRA Input capture WPAD: Write to PADDR WPA: Write to port A RPA: Read port A n = 4 to 6 Figure C.10 (c) Port A Block Diagram (Pins PA4 to PA6) Rev. 2.0, 03/01, page 803 of 822 Software standby External bus released Hardware standby Bus controller Reset R Q PA7DDR C WPAD Reset R Q PA7DR C D D Internal address bus Internal data bus Address output enable TPC PA7 TPC output enable Next data WPA Output trigger ITU Output enable Compare match output PRA Input capture WPAD: Write to PADDR WPA: Write to port A RPA: Read port A Figure C.10 (d) Port A Block Diagram (Pin PA7) Rev. 2.0, 03/01, page 804 of 822 C.11 Port B Block Diagrams Reset Internal data bus R Q PB n DDR C WPBD Reset R PBn Q PB n DR C D D TPC TPC output enable Next data WPB Output trigger ITU Output enable Compare match output RPB Input capture WPBD: Write to PBDDR WPB: Write to port B RPB: Read port B n = 0 to 3 Figure C.11 (a) Port B Block Diagram (Pins PB0 to PB3) Rev. 2.0, 03/01, page 805 of 822 R Q PB n DDR C WPBD Reset R PBn Q PB n DR C D D Internal data bus Reset TPC TPC output enable Next data WPB Output trigger ITU Output enable Compare match output RPB WPBD: Write to PBDDR WPB: Write to port B RPB: Read port B n = 4 or 5 Figure C.11 (b) Port B Block Diagram (Pins PB4, PB5) Rev. 2.0, 03/01, page 806 of 822 R Q PB 6 DDR C WPBD Reset R PB6 Q PB6 DR C D D Internal data bus Reset TPC TPC output enable Next data WPB Output trigger Bus controller CS7 output Chip select enable DMAC RPB WPBD: Write to PBDDR WPB: Write to port B RPB: Read port B DREQ0 input Figure C.11 (c) Port B Block Diagram (Pin PB6) Rev. 2.0, 03/01, page 807 of 822 R Q PB 7 DDR C WPBD Reset R PB7 Q PB7 DR C D D Internal data bus WPB Reset TPC TPC output enable Next data Output trigger RPB DMAC WPBD: Write to PBDDR WPB: Write to port B RPB: Read port B DREQ1 input A/D converter ADTRG input Figure C.11 (d) Port B Block Diagram (Pin PB7) Rev. 2.0, 03/01, page 808 of 822 Appendix D Pin States D.1 Port States in Each Mode Port States Hardware Standby Mode Software Standby Mode H T keep T 7 P27 to P20 1 to 4 5, 6 T L T T T T keep T keep T 7 P37 to P30 P47 to P40 1 to 6 7 1 to 6 8-bit bus 16-bit bus 7 P53 to P50 1 to 4 5, 6 T T T T T T L T T T T T T T T T keep T keep keep T keep T keep T 7 T T keep BusReleased Mode Program Execution, Sleep Mode Table D.1 Pin Name P17 to P10 Mode -- 1 to 4 5, 6 Reset Clock output T L T T T Clock output Clock output T T T -- T T T -- T -- keep T -- T T T -- A7 to A0 Input port (DDR = 0) A7 to A0 (DDR = 1) I/O port A15 to A8 Input port (DDR = 0) A15 to A8 (DDR = 1) I/O port D15 to D8 I/O port I/O port D7 to D0 I/O port A19 to A16 Input port (DDR = 0) A19 to A16 (DDR = 1) I/O port Rev. 2.0, 03/01, page 809 of 822 Pin Name P60 Mode 1 to 6 7 Reset T T T Hardware Standby Mode T T T Software Standby Mode keep keep keep (BRLE = 0) T (BRLE = 1) BusReleased Mode keep -- T Program Execution, Sleep Mode I/O port :$,7 I/O port I/O port %5(4 P61 1 to 6 7 P62 1 to 6 T T T T keep keep (BRLE = 0) H (BRLE = 1) -- L I/O port I/O port (BRLE = 0) or %$&. (BRLE = 1) I/O port $6, 5', +:5, /:5 I/O port 1 7 P66 to P63 1 to 6 7 P77 to P70 P80 1 to 7 1 to 6 T H*2 T T T T T T T T keep T keep T -- T -- T* Input port keep keep I/O port (RFSHE = 0) (RFSHE = 0) (RFSHE = 0) or 5)6+ 5)6+ H (RFSHE = 1) (RFSHE = 1) (RFSHE = 1) keep T (DDR = 0) H (DDR = 1) -- keep (DDR = 0) H (DDR = 1) -- keep (DDR = 0) H (DDR = 1) -- keep*1 I/O port Input port (DDR = 0) or &63 to &61 (DDR = 1) I/O port Input port (DDR = 0) or &60 (DDR = 1) I/O port I/O port 7 P83 to P81 1 to 6 T T T T 7 P84 1 to 6 T L T T keep T (DDR = 0) L (DDR = 1) 7 P96 to P90 1 to 7 T T T T keep keep Rev. 2.0, 03/01, page 810 of 822 Pin Name PA3 to PA0 PA6 to PA4 Mode 1 to 7 3, 4, 6 Reset T T*3 Hardware Standby Mode T T Software Standby Mode keep H (CS output) T (address output) keep (otherwise) BusReleased Mode keep*1 H (CS output) T (address output) keep (otherwise) keep*1 T keep*1 keep*1 H (CS output) keep (otherwise) keep*1 Program Execution, Sleep Mode I/O port &66 to &64 (CS output) A23 to A21 (address output) I/O port (otherwise) I/O port A20 I/O port I/O port &67 (CS output) I/O port (otherwise) I/O port 1, 2, 5, 7 PA7 PB7, PB5 to PB0 PB6 3, 4, 6 1, 2, 5, 7 1 to 7 3, 4, 6 T*3 L*3 T*3 T T T T T T T keep T keep keep H (CS output) keep (otherwise) 1, 2, 5, 7 T T keep Legend H: High L: Low T: High-impedance state keep: Input pins are in the high-impedance state; output pins maintain their previous state. DDR: Data direction register bit Notes: 1. The bus cannot be released in mode 7. 2. During direct power supply, oscillation damping time is "H" or "T". 3. During direct power supply, oscillation damping time differs between "H", "L" and "T". Rev. 2.0, 03/01, page 811 of 822 D.2 Pin States at Reset Reset in T1 State: Figure D.1 is a timing diagram for the case in which 5(6 goes low during the T1 state of an external memory access cycle. As soon as 5(6 goes low, all ports are initialized to the input state. $6, 5', +:5, and /:5 go high, and the data bus goes to the high-impedance state. The address bus is initialized to the low output level 0.5 state after the low level of 5(6 is sampled. Sampling of 5(6 takes place at the fall of the system clock (). Access to external address T1 T2 T3 Internal reset signal Address bus H'000000 0 High impedance 7 to 1 High (read access) High , (write access) Data bus (write access) I/O port High High impedance High impedance Figure D.1 Reset during Memory Access (Reset during T1 State) Rev. 2.0, 03/01, page 812 of 822 Reset in T2 State: Figure D.2 is a timing diagram for the case in which 5(6 goes low during the T2 state of an external memory access cycle. As soon as 5(6 goes low, all ports are initialized to the input state. $6, 5', +:5, and /:5 go high, and the data bus goes to the high-impedance state. The address bus is initialized to the low output level 0.5 state after the low level of 5(6 is sampled. The same timing applies when a reset occurs during a wait state (TW). Access to external address T1 T2 T3 Internal reset signal Address bus H'000000 0 High impedance 7 to 1 (read access) , (write access) Data bus (write access) I/O port High impedance High impedance Figure D.2 Reset during Memory Access (Reset during T2 State) Rev. 2.0, 03/01, page 813 of 822 Reset in T3 State: Figure D.3 is a timing diagram for the case in which 5(6 goes low during the T3 state of an external three-state space access cycle. As soon as 5(6 goes low, all ports are initialized to the input state. $6, 5', +:5, and /:5 go high, and the data bus goes to the highimpedance state. The address bus outputs are held during the T3 state. The same timing applies when a reset occurs in the T2 state of an access cycle to a two-state-access area. Access to external address T1 T2 T3 Internal reset signal Address bus H'000000 0 High impedance 7 to 1 (read access) , (write access) Data bus (write access) I/O port High impedance High impedance Figure D.3 Reset during Memory Access (Reset during T3 State) Rev. 2.0, 03/01, page 814 of 822 Appendix E Timing of Transition to and Recovery from Hardware Standby Mode E.1 Timing of Transition to Hardware Standby Mode (1) To retain RAM contents with the RAME bit set to 1 in SYSCR, drive the 5(6 signal low 10 system clock cycles before the 67%< signal goes low, as shown below. The minimum delay from the fall of the 67%< signal to the rise of the 5(6 signal is 0 ns. t1 10tcyc t2 0 ns Figure E.1 Timing of Recovery from Hardware Standby Mode (1) (2) To retain RAM contents with the RAME bit cleared to 0 in SYSCR, or when RAM contents do not need to be retained, 5(6 does not have to be driven low as in (1). E.2 Timing of Recovery from Hardware Standby Mode Drive the 5(6 signal low approximately 100 ns before 67%< goes high. t 100 ns tOSC Figure E.1 Timing of Recovery from Hardware Standby Mode (2) Rev. 2.0, 03/01, page 815 of 822 Appendix F Product Code Lineup Table F.1 H8/3052F Product Code Lineup Product Code 5 V version HD64F3052TE HD64F3052F Mark Code HD64F3052TE HD64F3052F HD64F3052BTE HD64F3052BF HD64F3052BVTE HD64F3052BVF Package (Hitachi Package Code) 100-pin TQFP (TFP-100B) 100-pin QFP (FP-100B) 100-pin TQFP (TFP-100B) 100-pin QFP (FP-100B) 100-pin TQFP (TFP-100B) 100-pin QFP (FP-100B) Product Type H8/3052 F-ZTAT H8/3052 F-ZTAT 5 V version HD64F3052BTE B mask version HD64F3052BF 3 V version HD64F3052BVTE HD64F3052BVF Rev. 2.0, 03/01, page 816 of 822 Appendix G Package Dimensions Figure G.1 shows the FP-100B package dimensions of the H8/3052 F-ZTAT. Figure G.2 shows the TFP-100B package dimensions. Unit: mm 16.0 0.3 14 75 76 16.0 0.3 51 50 0.5 100 1 *0.22 0.05 0.20 0.04 25 2.70 0.08 M 1.0 26 3.05 Max *0.17 0.05 0.15 0.04 1.0 0 - 8 0.5 0.2 0.10 0.12 +0.13 -0.12 *Dimension including the plating thickness Base material dimension Hitachi Code JEDEC EIAJ Weight (reference value) FP-100B -- Conforms 1.2 g Figure G.1 Package Dimensions (FP-100B) Rev. 2.0, 03/01, page 817 of 822 Unit: mm 16.0 0.2 14 75 76 16.0 0.2 51 50 100 1 *0.22 0.05 0.20 0.04 25 0.08 M 1.0 26 *0.17 0.05 0.15 0.04 1.20 Max 1.00 0.5 1.0 0 - 8 0.5 0.1 0.10 0.10 0.10 *Dimension including the plating thickness Base material dimension Hitachi Code JEDEC EIAJ Weight (reference value) TFP-100B -- Conforms 0.5 g Figure G.2 Package Dimensions (TFP-100B) Rev. 2.0, 03/01, page 818 of 822 Appendix H Differences from H8/3048F-ZTAT Table H.1 Item Pin specifications Differences between H8/3052F-ZTAT and H8/3048F-ZTAT H8/3048F-ZTAT Pin 1 VCC H8/3052F-ZTAT 5V Operation Pin 1 VCL Connected to VSS, with external connection of 0.1 F capacitor 3V Operation Pin 1 VCC Connected to system power supply Pin 10 VPP/5(62 Pin 10 FWE 512 kbytes single-power-supply flash memory 8 kbytes RAM VCC single power supply FWE function only (RESO function eliminated) FWE = 1 MD1 0 1 1 MD0 1 0 1 Mode 5 Mode 6 Mode 7 Set to: mode 1 in case of mode 5 mode 2 in case of mode 6 mode 3 in case of mode 7 Reset release MD2 0 0 0 MD1 0 1 1 MD0 1 0 1 ROM/RAM 128 kbytes dual-power-supply flash memory 4 kbytes RAM 12 V application Multiplexed as RESO pin 5(62 = 12 V MD2 Mode 5 Mode 6 Mode 7 12 V 12 V 12 V Program/erase voltage Vpp pin function Boot mode setting method Reset release User program mode setting method 5(62 = 12 V MD2 Mode 5 Mode 6 Mode 7 1 1 1 MD1 0 1 1 MD0 1 0 1 FWE = 1 MD2 Mode 5 Mode 6 Mode 7 1 1 1 MD1 0 1 1 MD0 1 0 1 Reset release Programming processing Block corresponding to programming addresses is set in EBR1/EBR2 before programming Reset release No setting Rev. 2.0, 03/01, page 819 of 822 Item FLMCR H8/3048F-ZTAT FLMCR (H'FF40) VPP VPPE EV PV E P H8/3052F-ZTAT FLMCR1 (H'FF40) FWE SWE1 ESU1 PSU1 EV1 PV1 E1 P1 FLMCR2 (H'FF41) FLER SWE2 ESU2 PSU2 EV2 PV2 E2 P2 EBR EBR1 (H'FF42) LB7 LB6 LB5 LB4 LB3 LB2 LB1 LB0 EBR1 (H'FF42) EB7 EB6 EB5 EB4 EB3 EB2 EB1 EB0 EBR2 (H'FF43) SB7 SB6 SB5 SB4 SB3 SB2 SB1 SB0 EBR2 (H'FF43) EB15 EB14 EB13 EB12 EB11 EB10 EB9 EB8 Multiple bits can be selected (set when programming/erasing) RAMCR RAMCR (H'FF48) FLER RAMS RAM2RAM1RAM0 Only one bit can be selected (set when erasing) RAMCR (H'FF47) RAMS RAM2RAM1 RAM0 Flash memory 16 blocks block configuration 16 kbytes x 8:LB0 to LB6 12 kbytes x 1:LB7 512 bytes x 8:SB0 to SB7 Flash memory H'00000 LB0 (16 kbytes) LB1 (16 kbytes) LB2 (16 kbytes) LB3 (16 kbytes) LB4 (16 kbytes) LB5 (16 kbytes) LB6 (16 kbytes) LB7 (12 kbytes) SB0 (512 bytes) SB1 (512 bytes) SB2 (512 bytes) SB3 (512 bytes) SB4 (512 bytes) SB5 (512 bytes) SB6 (512 bytes) SB7 (512 bytes) H'1FFFF 16 blocks 4 kbytes x 8:EB0 to EB7 32 kbytes x 1:EB8 64 kbytes x 7:EB9 to EB15 Flash memory EB0 (4 kbytes) EB1 (4 kbytes) EB2 (4 kbytes) EB3 (4 kbytes) EB4 (4 kbytes) EB5 (4 kbytes) EB6 (4 kbytes) EB7 (4 kbytes) EB8 (32 kbytes) EB9 (64 kbytes) EB10 (64 kbytes) EB11 (64 kbytes) EB12 (64 kbytes) EB13 (64 kbytes) EB14 (64 kbytes) EB15 (64 kbytes) H'7FFFF H'00000 Rev. 2.0, 03/01, page 820 of 822 Item RAM emulation block configuration H8/3048F-ZTAT On-chip RAM H'EF10 H'F000 H'F1FF H8/3052F-ZTAT Flash memory H'00000 On-chip RAM H'DF10 H'F000 Flash memory H'00000 H'01000 H'02000 H'03000 H'04000 H'1FFFF H'1F000 H'1F200 H'EFFF H'1F400 H'1F600 H'1F800 H'FF0F H'1FA00 H'FF0F H'1FC00 H'1FE00 H'1FFFF H'05000 H'06000 H'07000 H'08000 H'7FFFF Refresh controller In modes 1 to 6, DRAM or PSRAM can be directly connected to area 3. In modes 1, 2, 3, 4, and 6, DRAM or PSRAM can be directly connected to area 3. Cannot be used in mode 5 (because flash area overlaps area 3). DMAC registers MAR0AR, MAR0BR, MAR1AR, MAR1BR MAR0AR (H'FF20), MAR0BR (H'FF28), MAR1AR (H'FF30), MAR1BR (H'FF38) MAR0AR (H'FF20), MAR0BR (H'FF28), MAR1AR (H'FF30), MAR1BR (H'FF38) All bits are reserved; they always return 1 All bits are reserved; they return an undefined value if read, and cannot be if read, and cannot be modified. modified. ADCR (H'FFE9) Initial value: H'7F Bit 7 only is readable/writable. Other bits are reserved; they always return 1 if read, and cannot be modified. RSTCSR (H'FFAB) Initial value: '3F Bits 7 and 6 only are readable/writable. Other bits are reserved; they always return 1 if read, and cannot be modified. ADCR (H'FFE9) Initial value: H'7E Bit 7 only is readable/writable. Bit 0 is reserved, and must not be set to 1. Other bits are reserved; they always return 1 if read, and cannot be modified. RSTCSR (H'FFAB) Initial value: '3F Bit 7 only is readable/writable. Bit 6 is reserved, and must not be set to 1. Other bits are reserved; they always return 1 if read, and cannot be modified. A/D register ADCR WDT register RSTCSR Note: The H8/3052F-ZTAT program/erase procedures are different from those of the H8/3048F-ZTAT. Rev. 2.0, 03/01, page 821 of 822 Rev. 2.0, 03/01, page 822 of 822 H8/3052 F-ZTATTM Hardware Manual Publication Date: 1st Edition, January 2000 2nd Edition, March 2001 Published by: Electronic Devices Sales & Marketing Group Semiconductor & Integrated Circuits Hitachi, Ltd. Edited by: Technical Documentation Group Hitachi Kodaira Semiconductor Co., Ltd. Copyright (c) Hitachi, Ltd., 2000. All rights reserved. Printed in Japan.

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