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| 2.5V SEQUENTIAL FLOW-CONTROL DEVICE 36 BIT WIDE CONFIGURATION For use with 128Mb to 256Mb DDR SDRAM ADVANCE INFORMATION IDT72T6360 FEATURES * Product to be used with single or multiple external DDR SDRAM to provide significant storage capability of up to 1Gb density * IDT Standard mode or FWFT mode of operation * Empty and full flags for monitoring memory status * Programmable Almost-Empty and Almost-Full flags, each flag can default to one of four preselected offsets or serially programmed to a specific value * Selectable synchronous/asynchronous timing modes for Almost-Empty and Almost-Full flags * Master Reset clears all data and settings * Partial Reset clears data, but retains programmable settings * Depth expandable with multiple devices for densities greater than 1Gb * Width expandable with multiple devices for bus widths greater than 36 bits * JTAG functionality (Boundary Scan) * Available in a 324-pin PBGA, 1mm pitch, 19mm x 19mm * HIGH performance 0.18m CMOS technology * Industrial temperature range (-40C to +85C) is available * Supports industry standard DDR specifications, including Samsung, Micron, and Infineon memories * 166MHz operation (6ns read/write cycle time) * User selectable input and output port bus-sizing - x36in to x36out - x36in to x18out - x36in to x9out - x18in to x36out - x18in to x18out - x18in to x9out - x9in to x36out - x9in to x18out - x9in to x9out For other bus configurations see IDT72T6480 (x12, x24, or x48) 2.5V-LVTTL or 3.3V-LVTTL independently configured ports Independent and simultaneous read and write access User selectable synchronous/asynchronous read and write port timing * * * * FUNCTIONAL BLOCK DIAGRAM FWFT I/O Bus Configuration 36-bits FF/IR PAF EF/OR PAE Flag Logic Reset Logic FSEL[1:0] IDT72T6360 Sequential Flow Control Device MRS PRS IOSEL BM[3:0] 36-bits x36, x18, or x9 Output Register Input Register x36, x18, or x9 36-bits WEN WCLK/WR WCS ASYW Read Control Logic Write Control Logic REN RCLK/RD RCS ASYR DDR SDRAM Control Logic CK MCLK CK DQS WE CAS RAS Addr Data JTAG Control (Boundary Scan) TDO/SO TCK/SCLK TMS TDI/SI 8 13 64 6357 drw01 High Density DDR SDRAM x16, x32, x36, or x64 128Mb to 256Mb IDT and the IDT logo are registered trademarks of Integrated Device Technology, Inc COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES 1 2003 Integrated Device Technology, Inc. All rights reserved. Product specifications subject to change without notice. OCTOBER 2003 DSC-6357/- IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES List of Contents Features ......................................................................................................................................................................................................................... 1 Device Overview ............................................................................................................................................................................................................ 4 Pin Configuration ............................................................................................................................................................................................................. 6 Pin Descriptions ............................................................................................................................................................................................................... 7 Detailed Descriptions ..................................................................................................................................................................................................... 11 Functional Descriptions .................................................................................................................................................................................................. 17 Signal Descriptions ........................................................................................................................................................................................................ 18 Device Characteristics ................................................................................................................................................................................................... 22 Test Conditions .............................................................................................................................................................................................................. 24 AC Electrical Characteristics ........................................................................................................................................................................................... 25 JTAG Timing Specifications ............................................................................................................................................................................................ 40 Depth Expansion Configuration ..................................................................................................................................................................................... 44 Width Expansion Configuration ...................................................................................................................................................................................... 45 List of Tables Table 1 - DDR SDRAM Specifications ........................................................................................................................................................................... 11 Table 2 - Supported Memory Vendors .......................................................................................................................................................................... 11 Table 3 - Total Possible External Memory Configurations ............................................................................................................................................... 12 Table 4 - DDR SDRAM Static Connections .................................................................................................................................................................... 13 Table 5 - Maximum I/O Operating Frequency Based On Various Configurations ............................................................................................................ 14 Table 6 - Error Detection and Correction Configuration .................................................................................................................................................. 14 Table 7 - Memory Configurations Settings ..................................................................................................................................................................... 16 Table 8 - Device configuration ....................................................................................................................................................................................... 17 Table 9 - Default Programmable Flag Offsets ................................................................................................................................................................. 17 Table 10 - Number of Bits Required for Offset Registers ................................................................................................................................................. 17 Table 11 - Bus-Matchings .............................................................................................................................................................................................. 19 Table 12 - MTYPE[1:0] Configurations .......................................................................................................................................................................... 20 2 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES List of Figures Figure 1. Sequential Flow-Control Device Block Diagram ................................................................................................................................................ 5 Figure 2a. Configuration 1 - Two Chip Solution .............................................................................................................................................................. 13 Figure 2b. Configuration 2 - Two Chip Solution .............................................................................................................................................................. 13 Figure 2c. Configuration 3 - Three Chip Solution ........................................................................................................................................................... 13 Figure 2d. Configuration 4 - Three Chip Solution ........................................................................................................................................................... 13 Figure 2e. Configuration 5 - Three Chip Solution ........................................................................................................................................................... 13 Figure 2f. Configuration 6 - Four Chip Solution .............................................................................................................................................................. 13 Figure 2g. Configuration 7 - Five Chip Solution .............................................................................................................................................................. 13 Figure 3. Memory Interface Connection (Single Chip) .................................................................................................................................................... 15 Figure 4. Memory Interface Connection (Two Chip) ....................................................................................................................................................... 15 Figure 5a. AC Test Load ................................................................................................................................................................................................ 24 Figure 5b. Lumped Capacitive Load, Typical Derating ................................................................................................................................................... 24 Figure 6. Master Reset and Initialization ......................................................................................................................................................................... 27 Figure 7. Partial Reset ................................................................................................................................................................................................... 28 Figure 8. Write First Word Cycles - IDT Standard Mode ................................................................................................................................................. 29 Figure 9. Write First Word Cycles - FWFT Mode ............................................................................................................................................................ 29 Figure 10. Empty Boundary - IDT Standard Mode ........................................................................................................................................................ 30 Figure 11. Empty Boundary - FWFT Mode .................................................................................................................................................................... 30 Figure 12. Full Boundary - IDT Standard Mode ............................................................................................................................................................ 31 Figure 13. Full Boundary - FWFT Mode ....................................................................................................................................................................... 31 Figure 14. Output Enable ............................................................................................................................................................................................... 32 Figure 15. Read Chip Select ......................................................................................................................................................................................... 32 Figure 16. Write Chip Select .......................................................................................................................................................................................... 32 Figure 17. Bus-Matching Configuration - x36 In to x18 Out - IDT Standard Mode ......................................................................................................... 33 Figure 18. Bus-Matching Configuration - x36 In to x9 Out - IDT Standard Mode ............................................................................................................ 33 Figure 19. Bus-Matching Configuration - x18 In to x36 Out - IDT Standard Mode .......................................................................................................... 34 Figure 20. Bus-Matching Configuration - x9 In to x36 Out - IDT Standard Mode ............................................................................................................ 34 Figure 21. Synchronous PAE Flag - IDT Standard Mode and FWFT Mode ................................................................................................................... 35 Figure 22. Synchronous PAF Flag - IDT Standard Mode and FWFT Mode ................................................................................................................... 35 Figure 23. Asynchronous Read and PAF Flag - IDT Standard Mode ............................................................................................................................. 36 Figure 24. Asynchronous Write and PAE Flag - IDT Standard Mode .............................................................................................................................. 36 Figure 25. Asynchronous Write and PAF Flag - IDT Standard Mode .............................................................................................................................. 36 Figure 26. Asynchronous Empty Boundary - IDT Standard Mode .................................................................................................................................. 37 Figure 27. Asynchronous Full Boundary - IDT Standard Mode...................................................................................................................................... 37 Figure 28. Asynchronous Read and PAE Flag - IDT Standard Mode ............................................................................................................................. 37 Figure 29. Serial Loading of Programmable Flag Registers (IDT Standard and FWFT Modes) ...................................................................................... 38 Figure 30. Reading of Programmable Flag Registers (IDT Standard and FWFT Modes) ............................................................................................... 38 Figure 31. Standard JTAG Timing ................................................................................................................................................................................. 39 Figure 32. JTAG Architecture ......................................................................................................................................................................................... 40 Figure 33. TAP Controller State Diagram ....................................................................................................................................................................... 41 Figure 34. Depth Expansion Configuration in IDT Standard Mode ................................................................................................................................. 44 Figure 35. Depth Expansion Configuration in FWFT Mode ............................................................................................................................................ 44 Figure 36. Width Expansion Configuration in IDT Standard Mode and FWFT Mode ....................................................................................................... 45 3 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES DESCRIPTION The IDT72T6360 sequential flow-control device is a device incorporating a seamless connection to external DDR SDRAM for significant storage capacity supporting high-speed applications. Both read and write ports of the sequential flow-control can operate independently at up to 166MHz. There is a user selectable correction feature that will correct any erroneous single data bit when reading from the SDRAM. The independent read and write ports each has associated read and write clocks, enables, and chip selects. Both ports can operate either synchronously or asynchronously. Other features include bus-matching, programmable status flags with selectable synchronous/asynchronous timing modes, IDT Standard or FWFT mode timing, and JTAG boundary scan functionality. The bus-matching feature will allow the inputs and outputs to be configured to x36, x18, or x9 bus width. There are four default offset values available for the programmable flags (PAE/PAF), as well as the option of serially programming the offsets to a specific value. The device package is 19mm x 19mm 324-pin PBGA. It operates at a 2.5V core voltage with selectable 2.5V or 3.3V I/Os. The I/O interface to the SDRAM will be 2.5V SSTL only and not 3.3V tolerant. Both industrial and commercial temperature ranges will be offered. The sequential flow-control device controls individual DDR SDRAM of either 128Mb or 256Mb. The device will support industry standard DDR specification memories (note DDR II is not supported), which include vendors such as Samsung, Micron, and Infineon. The data bus connected to the DDR SDRAM can be 16-bit, 32-bit, or 64-bits wide. The sequential flow-control device can independently control up to four separate external memories for a maximum of density of 1Gb (128MB). Depth expansion mode is available for applications that require more than 1Gb of storage memory. 4 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES D[35:0] 36 Input Register Output Register 36 Q[35:0] 36 36 Input Bus-Matching Logic Output Bus-Matching Logic QP Cache Control Logic Refresh Counter 144 144 144 144 QP Cache 72 x 36 QP Cache 72 x 36 Multi-Clock Arbitration Circuits State Machine Memory Interface 72 optional 72 bypass 72 optional 72 bypass Error 72 Detection Correction Check Bit Generator Error 72 72 Detection Correction Check Bit Generator 72 Logic Control Circuits DQS[7:0] DQ[63:0] ADDR[12:0] optional bypass 72 Memory 13 Interface BA[1:0] Address and WE Control CAS RAS CK CK 72 optional bypass 72 72 Memory Interface Data and Bus-Matching DLL PLL MCLK 64 DQ[63:0] 8 DQS[7:0] TMS TDI TCK JTAG TDO 6357 drw02 Figure 1. Sequential Flow-Control Device Block Diagram 5 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES PIN CONFIGURATION A1 BALL PAD CORNER A GND GND DQ10 DQ8 DQ4 DQ1 CK A1 A5 A9 WE RAS DQ35 DQ36 DQ38 DQ40 GND GND B GND GND DQS1 DQ9 DQ5 DQ2 AVCC A0 A4 A10 BA1 DQ32 DQS4 DQ39 DQ44 DQS5 GND GND C DQ14 DQ13 DQ11 DQ12 DQ6 DQ3 CK A2 A6 A11 BA0 DQ34 DQ37 DQ41 DQ47 DQ45 DQ49 DQ50 D DQ16 DQ15 DQ17 DQ7 DQS0 DQ0 AVCC A3 A7 A8 A12 CAS DQ33 DQ43 DQ46 VREF DQ51 DQS6 E DQ19 DQ18 DQS2 DQ20 DQ21 AGND AGND VCC VCC VCC VCC VCC VCC DQ42 F DQ23 DQ22 DQ24 DQ25 DQ26 VCC VCC VCC VCC VCC VCC VCC VCC DQ59 G DQS3 DQ27 DQ28 DQ29 DQ30 VCC VCC GND GND GND GND H MCLK DQ31 D0 D1 D2 VCC GND GND GND J D4 D3 D5 D6 D7 VCC GND K D11 D12 D10 D9 D8 VCC GND L D16 D17 D15 D14 M D21 D22 D20 D19 N D26 D27 D25 P D31 D32 D30 P D24 D29 VCC VCC VCC VCC E R D13 VCC VCC D18 VCC VCC D23 VCC VCC D28 FSEL1 VCC FSEL0 VCC ASYW VCC PRS MRS ASYR WEN I L GND GND GND VCC VCC GND WCLK GND GND I M GND GND GND GND GND GND GND GND GND GND VCC VCC MIC0 JSEL MIC1 TDI/SI TMS SWEN MIC2 TCK/ SCLK SREN A N VCC VCC VCC GND VDDQ VDDQ GND VDDQ VDDQ GND VDDQ VDDQ GND VDDQ VDDQ VDDQ VDDQ VDDQ VDDQ VDDQ Q23 TDO/SO DNC Q32 FF/ IR PAF DNC DNC Y R DQ54 DQ48 DQ52 DQ58 DQ55 DQ56 DQ62 DQ61 DQS7 Q2 Q1 DQ63 Q6 Q5 Q3 Q7 Q12 Q8 Q13 Q11 Q10 Q28 Q15 Q16 Q29 Q19 Q20 Q33 Q31 Q25 DQ53 DQ57 DQ60 Q0 Q4 Q9 GND Q14 GND Q17 VCC Q18 IOSEL BM3 Q21 R D34 D35 D33 IDEM MTYPE0 BM2 Q34 Q30 Q26 Q22 T VCC VCC VCC WCS MSPEED BM1 DNC DNC Q35 DNC Q27 Q24 U GND GND VCC FWFT MTYPE1 BM0 OE PAE DNC DNC DNC GND GND V GND GND VCC RCLK REN RCS EF/ OR DNC DNC DNC GND GND 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 6357 drw03 PBGA (BB324-1, order code: BB) TOP VIEW 6 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES PIN DESCRIPTIONS Symbol A[12:0] ASYR(1) Pin No. Name Location See Pin Memory Address Bus No. table V6 Asynchronous Read Port Asynchronous Write Port Memory Bank Address Input Bit Memory Clock Memory Column Address Strobe Memory Data Bus I/O TYPE Description OUTPUT Output address bus to be connected to the input address bus of the external memory to provide row and column address. A HIGH on this input during master reset will select synchronous read operation for the output port. A LOW will select asynchronous operation. If asynchronous is selected the device must operate in IDT Standard mode and the read enable must be tied to GND. INPUT A HIGH on this input during master reset will select synchronous write operation for the input port. A LOW will select asynchronous operation. If asynchronous is selected the device must operate in IDT Standard mode and the write enable must be tied to GND. OUTPUT Address bits to be connected to the external memory's BA inputs to determine which bank an ACTIVE, READ, WRITE, or PRECHARGE command is being applied. INPUT Selects the bus width of the read and write ports. OUTPUT Clock output to be connected to the external memory's input clock. OUTPUT Output enable signal to be connected to the external memory's CAS pin to activate and deactivate the column address strobe. INPUT Data inputs for a 36, 18, and 9-bit bus. BiInput/output data bus for the external memory's data bus. Directional BiInput/output data strobe to be connected to the external memory's data strobe. Directional OUTPUT In IDT Standard mode, the EF function is selected. EF indicates whether or not the device memory is empty. In FWFT mode, the OR function is selected. OR indicates whether or not there is valid data available at the outputs. OUTPUT In IDT Standard mode, the FF function is selected. FF indicates whether or not the device memory is full. In FWFT mode, the IR function is selected. IR indicates whether or not there is space available for writing to the device memory. INPUT INPUT INPUT During master reset, these inputs will select one of four default values for the programmable flags PAE and PAF. The selected value will apply to both PAE and PAF offset. During master reset, a HIGH on this input selects FWFT timing mode. A LOW selects IDT Standard timing mode. This select pin is used for depth expansion configuration in IDT Standard mode. If this pin is tied HIGH, then the FF/IR signal will be inverted to provide a seamless depth expansion interface. If this pin is tied LOW, the depth expansion in IDT Standard mode will be deactivated. This input determines whether the inputs and outputs will tolerate a 2.5V or 3.3V voltage signals. If IOSEL is HIGH, then all I/Os will be 2.5V tolerant. If IOSEL is LOW, then all I/Os will be 3.3V tolerant. This pin selects whether the JTAG pins will be used for serial programming. If JSEL is HIGH, the JTAG pins will only be used for JTAG boundary-scan function. If JSEL is LOW, the JTAG function is disabled and the JTAG pins will be used for serial programming of the PAE/PAF offset registers. These signals enable the EDC feature of the device. See Table 6, Error Detection and Correction Configuration (EDC) for all possible configurations. 33MHz reference clock used to generate CK and CK for external memory interface. Master reset initializes the read and write pointers to zero and sets the output register to all zeros. All initialized settings for the device will be configured during master reset. INPUT ASYW(1) T6 BA[1:0] BA1-B11 BA0-C11 C7 A7 D12 BM[3:0](1) See Pin tbl. Bus-Matching Bit CK CK CAS D[35:0] DQ[63:0] DQS[7:0] EF/OR Memory Clock Inverted OUTPUT Differential clock output to be connected to the external memory's differential input clock. See Pin tbl. Data Inputs See Pin No. table See Pin Memory Data Strobe No. table V13 Empty Flag/ Output Ready Full Flag/Input Ready FF/IR R12 FSEL[1:0](1) FSEL1-P6 Flag Select Bit FSEL0-R6 FWFT(1) IDEM(1) U7 R7 First Word Fall Through IDT Standard Mode Depth Expansion Mode Select I/O VDDQ Select IOSEL(1) P7 INPUT JSEL(1) P11 JTAG Select INPUT MIC[2:0](1) MIC2-U10 Memory Configuration MIC1-R10 MIC0-P10 MCLK MRS H1 V5 Master Clock Master Reset INPUT INPUT INPUT 7 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES PIN DESCRIPTIONS (CONTINUED) Symbol MSPEED(1) Pin No. Name Location T8 Memory Speed I/O TYPE INPUT INPUT INPUT Description This input select the speed of the external memory interfacing the sequential flow-control device. A LOW selects 133MHz, and HIGH selects 166MHz. These inputs select which type of external memory is interfacing the sequential flow-control device. See Table 10 for the list of selectable memories. Asynchronous three-state control of the data outputs. All data outputs Q[35:0] will be placed in high-impedance if this pin is HIGH. Conversely, all data outputs will be active when this pin is LOW. MTYPE(1) MTYPE1-U8 Memory Type [1:0] MTYPE0-R8 [1:0] OE U12 Output Enable PAE U13 Programmable Almost Empty Flag OUTPUT This is the programmable almost empty flag that can be used as an early indicator for the empty boundary condition of the internal memory. PAE goes LOW if the number of words in the sequential flow-control device is less than offset n, which is stored in the empty offset register. PAE goes HIGH if the number of words in the sequential flow-control device is greater than or equal to the offset n. OUTPUT This is the programmable almost full flag that can be used as an early indicator for the full boundary condition of the internal memory. PAF goes HIGH if the number of free locations in the sequential flow-control device is more than offset m, which is stored in the full offset register. PAF goes LOW if the number of free locations in the sequential flow-control device is less than or equal to the offset m. INPUT Partial reset initializes the read and write pointers to zero and sets the output registers to all zeros. All existing configurations in the sequential flow-control device will not be affected. This includes the IDT Standard or FWFT mode timing, programmable flag settings, and bus width and data rate mode. PAF T12 Programmable Almost Full Flag PRS U6 Partial Reset Q[35:0] RAS RCLK/ RD See Pin tbl. Data Output Bus A12 V9 OUTPUT Data outputs for a 36, 18, and 9-bit bus. Memory Row Address OUTPUT Output strobe signal to be connected to the external memory's RAS pin to activate and Strobe deactivate the row address strobe. Read Clock/ Read Strobe INPUT This is a dual function pin. If synchronous operation of the read port is selected, the rising edge of RCLK reads data from the sequential flow-control device when REN is enabled. If asynchronous operation of the read port is selected, a rising edge on RD reads data from the sequential flow-control device without the need of a free-running input read clock. Synchronous three-state control of the data outputs. Provides another means of controlling the data outputs synchronous to RCLK. Can be regarded as a second output enable signal. REN enables RCLK for reading data from the sequential flow-control device. If asynchronous mode is selected on the read port, this signal should be tied to GND. When SREN is brought LOW before the rising edge of SCLK, the contents of the PAE and PAF offset registers are copied to a serial shift register. While SREN is maintained LOW, on each rising edge of SCLK, one bit of data is shifted out of this serial shift register through the SDO output pin. On each rising edge of SCLK when SWEN is LOW, data from the FWFT pin is serially loaded into the PAE and PAF registers. This is a dual function pin. When the JSEL pin is HIGH, this is the clock input for JTAG boundaryscan function. One of four terminals required by IEEE Standard 1149.1-1990. Test operations of the device are synchronous to TCK. Data from TMS and TDI are sampled on the rising edge of TCK and outputs change on the falling edge of TCK. When the JSEL pin is LOW, this is the serial clock input for writing and reading the PAE/PAF offset registers. On the rising edge of every SCLK when SWEN is LOW, one bit of data from the SI pin is shifted into the PAE and PAF offset registers. On the rising edge of each SCLK when SREN is LOW, one bit of data from the SO pin is shifted out of the PAE and PAF offset registers. If the JTAG or serial programming is not used this signal needs to be tied to GND. RCS REN SREN V12 V10 V11 Read Chip Select Read Enable Serial Read Enable INPUT INPUT INPUT SWEN TCK/ SCLK T11 U11 Serial Write Enable JTAG Clock/ Serial Clock INPUT INPUT 8 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES PIN DESCRIPTIONS (CONTINUED) Symbol TDI/SI Pin No. Name Location R11 JTAG Test Data Input/ Serial Input I/O TYPE INPUT Description This is a dual function pin. When the JSEL pin is HIGH, this is the JTAG test data input pin. One of four terminals required by IEEE Standard 1149.1-1990. During the JTAG boundary scan operation, test data serially loaded via the TDI on the rising edge of TCK to the Instruction Register, ID Register and Bypass Register. When the JSEL pin is LOW, this is the serial input pin for the PAE/PAF offset registers. An internal pull-up resistor forces TDI/SI HIGH if left unconnected. TDO/SO P12 JTAG Test Data Output/ OUTPUT This is a dual function pin. When the JSEL pin is HIGH, this is the JTAG test data output pin. Serial Output One of four terminals required by IEEE Standard 1149.1-1990. During the JTAG boundary scan operation, test data serially loaded output via the TDO on the falling edge of TCK from either the Instruction Register, ID Register and Bypass Register. This output is high-impedance except when shifting, while in SHIFT-DR and SHIFT-IR controller states. When the JSEL pin is LOW, this is the serial data output pin for the PAE/PAF offset registers. JTAG Mode Select INPUT TMS is a serial input pin. One of four terminals required by IEEE Standard 1149.1-1990. TMS directs the device through its TAP controller states. An internal pull-up resistor forces TMS HIGH if left unconnected. This is a dual function pin. If synchronous operation of the write port is selected, the rising edge of WCLK writes data into the sequential flow-control device when WEN is enabled. If asynchronous operation of the write port is selected, a rising edge on WR writes data into the sequential flow-control device without the need of a free-running input write clock. Synchronous three-state control of the data inputs. Provides a means of controlling the data inputs synchronous to WCLK. Typically used to avoid bus-contention when multiple devices are sharing the same input data bus. TMS T10 WCLK/WR V8 Write Clock/Write Strobe INPUT WCS T7 Write Chip Select INPUT WE WEN VCC AVCC VDDQ VREF GND AGND A11 V7 See Pin No. table B7, D7 See Pin No. table D16 E6, E7 Memory Write Enable Write Enable OUTPUT Output strobe signal to be connected to the external memory's WE pin to activate and deactivate the write address strobe. INPUT WEN enables WCLK for writing data into the sequential flow-control device. If asynchronous mode is selected on the write port, this signal should be tied to GND. The core power supply pins for the device as well as to the external DDR SDRAM. Needs to be connected to a +2.5V VCC power plane. The power supply pins for the internal PLL of the device. Needs to be connected to a +2.5V supply rail. This pin is used to provide power to the output drivers. The nominal values are 2.5V or 3.3V, depending on the state of the IOSEL pin. This is a voltage reference input to the SDRAM and must be connected to VCC/2 or 1.25V. The ground pins for the device that must be connected to the ground plane. The ground pins for the analog circuitry in the device that must be connected to the ground plane. Core VCC and Output Power voltage for DDR SDRAM Internal PLL VCC Output rail voltage for I/Os Reference Voltage Ground pin for analog circuit Power Power Power Ground Ground See Pin table Ground Pin NOTE: 1. These pins should not change after master reset. Please see next page for Pin Number Location Table 9 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES PIN NUMBER LOCATION TABLE Symbol A[12:0] BM[3:0] D[35:0] Name Memory Address Bus Bus-Matching Data Inputs I/O TYPE OUTPUT INPUT INPUT Pin Number A12-D11, A11-C10, A10-B11, A9-A10, A8-D10, A7-D9, A6-C9, A5-A9, A4-B9, A3-D8, A2-C8, A1-A8, A0-B8 BM3-P9, BM2-R9, BM1-T9, BM0-U9 D35-R2, D34-R1, D33-R3, D32-P2, D31-P1, D30-P3, D29-P4, D28-P5, D27-N2, D26-N1, D25-N3, D24-N4, D23-N5, D22-M2, D21-M1, D20-M3, D19-M4, D18-M5, D17-L2, D16-L1, D15-L3, D14-L4, D13-L5, D12-K2, D11-K1, D10-K3, D9-K4, D8-K5, D7-J5, D6-J4, D5-J3, D4-J1, D3-J2, D2-H5, D1-H4, D0-H3 DQ[63:0] Memory Data Bus BiDQ63-H17, DQ62-G15, DQ61-G16, DQ60-G18, DQ59-F14, DQ58-F15, DQ57-F18, DQ56-F17, Directional DQ55-F16, DQ54-E15, DQ53-E18, DQ52-E17, DQ51-D17, DQ50-C18, DQ49-C17, DQ48-E16, DQ47-C15, DQ46-D15, DQ45-C16, DQ44-B15, DQ43-D14, DQ42-E14, DQ41-C14, DQ40-A16, DQ39-B14, DQ38-A15, DQ37-C13, DQ36-A14, DQ35-A13, DQ34-C12, DQ33-D13, DQ32-B12, DQ31-H2, DQ30-G5, DQ29-G4, DQ28-G3, DQ27-G2, DQ26-F5, DQ25-F4, DQ24-F3, DQ23-F1, DQ22-F2, DQ21-E5, DQ20-E4, DQ19-E1, DQ18-E2, DQ17-D3, DQ16-D1, DQ15-D2, DQ14-C1, DQ13-C2, DQ12-C4, DQ11-C3, DQ10-A3, DQ9-B4, DQ8-A4, DQ7-D4, DQ6-C5, DQ5-B5, DQ4-A5, DQ3-C6, DQ2-B6, DQ1-A6, DQ0-D6, BiDQS7-G17, DQS6-D18, DQS5-B16, DQS4-B13, DQS3-G1, DQS2-E3, DQS1-B3, DQS0-D5 Directional Output Q35-T15, Q34-R15, Q33-P15, Q32-P14, Q31-P16, Q30-R16, Q29-N15, Q28-M15, Q27-T17, Q26-R17, Q25-P17, Q24-T18, Q23-N14, Q22-R18, Q21-P18, Q20-N17, Q19-N16, Q18-N18, Q17-M18, Q16-M17, Q15-M16, Q14-L18, Q13-L15, Q12-K16, Q11- L16, Q10-L17, Q9-K18, Q8-K17, Q7-K15, Q6-J15, Q5-J16, Q4-J18, Q3-J17, Q2-H15, Q1-H16, Q0-H18 E(8-13), F(6-13), G(6,7,12-14), H6, J6, K6, L(6,7), M(6-8), N(6-11), R(4,5), T(1-5), U(3-5), V(3,4) H(13,14), J(13,14), K(13,14), L(13,14), M(12-14), N(12,13) G(8-11), H(7-12), J(7-12), K(7-12), L(8-12), M(9-11), P8 P13, R(13,14), T(13,14,16), U(14-16), V(14-16) DQS[7:0] Memory Data Strobe Q[35:0] Data Output Bus VCC VDDQ GND DNC Core VCC & Output voltage for DDR SDRAM Output rail voltage for I/Os Ground Pin Do Not Connect Power Power Ground -- 10 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES DETAILED DESCRIPTIONS SEQUENTIAL FLOW-CONTROL STRUCTURE The IDT sequential flow-control (SFC) device is comprised of three interfaces: input port, output port, and memory interface. The input and output port can operate independently of each other with selectable bus widths of x9, x18, or x36 bits wide. The third interface, or memory interface, is connected directly to an external memory, which can be used to offload data entering the SFC device. WRITING AND READING FROM THE SEQUENTIAL FLOW-CONTROL DEVICE Writing into the SFC device is accomplished by setting the write enable signal (WEN) and write chip select (WCS) low with a free running write clock (WCLK). Data will be written on the rising edge of every WCLK into the Quad-Port (QP) cache of the SFC device. The internal state machine of the device will determine whether to send the data to the DDR SDRAM or send it directly through to the output bus, depending on when the data is to be accessed. This provides "data coherency" and minimizes the path that the data has to travel. Reading from the SFC device is accomplished by setting the read enable signal (REN) and read chip select (RCS) low with a free running read clock (RCLK). Data will be sent to the output bus on the rising edge of every RCLK. This data will be accessed either from the QP cache or the external DDR SDRAM. EXTERNAL MEMORY SELECTION The DDR SDRAM interface of the SFC device can support DDR SDRAM with standard DDR I specifications. The SFC device can support any external memory within the following characteristics: * * * Bus width: 16-bit or 32-bit wide Speed: 133MHz or 166MHz Density: 128Mb or 256Mb Table 1 lists the DDR SDRAM specifications that are required to meet the sequential flow-control device requirements. Table 2 lists the memory vendors and associated part numbers of DDR SDRAMs that have been validated by IDT to meet the requirements for the DDR SDRAM interface. TABLE 1 - DDR SDRAM SPECIFICATIONS DDR SDRAM Specifications DDR SDRAM Bus-Width 16-bit 32-bit CL 2.5 3 tRCWD 3 2 tWR 3 3 tRCDR 3 4 tRP 3 4 tRFC 12 14 tWR + tRP 6 7 Units ns ns TABLE 2 - SUPPORTED MEMORY VENDORS Density 128Mb 128Mb 128Mb 128Mb 256Mb 256Mb 256Mb 256Mb Bus Width 16 16 16 32 16 16 16 32 Vendor Samsung Micron Infineon Samsung Samsung Micron Infineon Samsung Part# K4M281638E-TCLB3 K4M281638E-TCLA2 MT46V8M16TG-6T MT46V8M16TG-75 HYB25D128160ATL-6 HYB25D128160ATL-7 K4D263238E-GC45 K4H561638F-TCLB3 K4H561638F-GCLB3 MT46V16M16TG-6T MT46V16M16TG-75 HYB25D256160BTL-6 HYB25D256160BTL-7 K4D553238E-JC50 11 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES * Two 16-bit devices connecting a x32 interface to the DDR SDRAM * Two 32-bit devices connecting a x36 interface to the DDR SDRAM * Two 32-bit devices connecting a x64 interface to the DDR SDRAM * Three 16-bit devices connecting a x36 interface to the DDR SDRAM * Four 16-bit devices connecting a x64 interface to the DDR SDRAM EXTERNAL MEMORY CONFIGURATIONS The DDR SDRAM interface of the sequential flow-control (SFC) device has a 64-bit output data bus that provides up to four (16-bit SDRAM) external DDR SDRAM connections. For multiple memory connections, they must be of the same density configuration and speed grade. For example, two device connected cannot consist of one 128Mb and one 256Mb memory nor two 128Mb with one at 133MHz and the other at 166MHz. Below is a summary of the possible configurations: * One 16-bit device connecting a x16 interface to the DDR SDRAM * One 32-bit device connecting a x32 interface to the DDR SDRAM These various configurations determine the storage density of the SFC device. The storage density can range from a minimum of 128Mb to a maximum of 1Gb. Table 3 lists the possible ways to connect the DDR SDRAMs and the number of chipset solutions to obtain the various storage densities. TABLE 3 - TOTAL POSSIBLE EXTERNAL MEMORY CONFIGURATIONS Two Chip Solution(1) Configuration 1, 2 1 x128Mb [4M x 32] Total memory: 128Mb 1 x 256Mb [8M x 32] Total memory: 256Mb 1 x 128Mb [8M x 16] Total memory: 128Mb 1 x 256Mb [16M x 16] Total memory: 256Mb (2) Three Chip Solution(1) (2) Four Chip Solution(1) (2) Five Chip Solution(1) (2) Configurations 3, 4, 5 2 x 128Mb [4M x 32] Total memory: 256Mb 2 x 256Mb [8M x 32] Total memory: 512Mb 2 x 128Mb [8M x 16] Total memory: 256Mb 2 x 256Mb [16M x 16] Total memory: 512Mb Configuration 6 N/A N/A Configuration 7 N/A N/A 3 x 128Mb [8M x 16] Total memory: 384Mb 3 x 256Mb [16M x 16] Total memory: 768Mb 4 x 128Mb [8M x 16] Total memory: 512Mb 4 x 256Mb [16M x 16] Total memory: 1Gb NOTES: 1. The chip solution number includes the sequential flow-control device and external DDR SDRAM 2. See Figure 2a-2g for the 7 different configurations referenced in the table above. 12 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES Below are the various chipset solution configurations available to the sequential flow-control device (see Figure 2a-2g). The external memory interface is designed to seamlessly connect one or more DDR SDRAMs. There are a number of pins on the DDR SDRAM that requires the user to tie to a specified state, which are listed in Table 4. DDR SDRAM: 128Mb [4Mb x 32] or 256Mb [8Mb x 32] Total Density: 256Mb or 512Mb 4 12 Data Bus 36 32 128Mb or 256Mb DDR SDRAM 6357 drw07 TABLE 4 - DDR SDRAM STATIC CONNECTIONS SDRAM Pin CKE CS DM Static Connections VCC GND GND IDT SFC Address Bus 12 Figure 2d. Configuration 4 - Three Chip Solution DDR SDRAM: 128Mb [4Mb x 32] or 256Mb [8Mb x 32] Total Density: 128Mb or 256Mb Data Bus 32 Address Bus 12 128Mb or 256Mb DDR SDRAM 6357 drw04 DDR SDRAM: 128Mb [8Mb x 16] or 256Mb [16Mb x 16] Total Density: 256Mb or 512Mb 16 13 Data Bus 32 16 128Mb or 256Mb DDR SDRAM 6357 drw08 IDT SFC IDT SFC Address Bus 13 Figure 2a. Configuration 1 - Two Chip Solution Figure 2e(1). Configuration 5 - Three Chip Solution DDR SDRAM: 128Mb [8Mb x 16] or 256Mb [16Mb x 16] Total Density: 128Mb or 256Mb Data Bus 16 Address Bus 13 (1) DDR SDRAM: 128Mb [8Mb x 16] or 256Mb [16Mb x 16] Total Density: 384Mb or 768Mb 4 13 16 IDT SFC 128Mb or 256Mb DDR SDRAM 6357 drw05 13 IDT SFC Data Bus 36 16 Address Bus 13 (1) 128Mb or 256Mb DDR SDRAM 6357 drw09 Figure 2b . Configuration 2 - Two Chip Solution Figure 2f . Configuration 6 - Four Chip Solution DDR SDRAM: 128Mb [4Mb x 32] or 256Mb [8Mb x 32] Total Density: 256Mb or 512Mb 32 12 Data Bus 64 32 128Mb or 256Mb DDR SDRAM 6357 drw06 DDR SDRAM: 128Mb [8Mb x 16] or 256Mb [16Mb x 16] Total Density: 512Mb or 1Gb 16 13 Data Bus IDT SFC IDT SFC 64 16 Address Bus 12 Address Bus 13 128Mb or 256Mb DDR SDRAM 6357 drw10 Figure 2c. Configuration 3 - Three Chip Solution NOTE: 1. * 12-bit address bus for 8Mb x16 * 13-bit address bus for 16Mb x16 Figure 2g . Configuration 7 - Five Chip Solution (1) 13 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES MAXIMUM I/O OPERATING FREQUENCY The sequential flow-control (SFC) device is designed to operate at the maximum frequency of 166MHz. There are certain configurations however, that will limit the maximum frequency of the input and output ports. The main factors that determine the usable memory are the I/O bus-width of the SFC, the density and number of DDR SDRAMs connected, and whether or not EDC is used. Table 5 lists the maximum frequency for the input and output ports of the SFC based on the various configurations. TABLE 5 - MAXIMUM I/O OPERATING FREQUENCY BASED ON VARIOUS CONFIGURATIONS SFC Bus-Width DDR SDRAM Freq (MHz) 133.33 x36 166.66 133.33 x18 166.66 133.33 x9 166.66 NOTE: 1. See Figure 2a-2g for a list of all configurations. With EDC on or off EDC on EDC off EDC on EDC off EDC on EDC off EDC on EDC off EDC on EDC off EDC on EDC off Configurations 3, 7 100 133.33 133.33 166.67 166.67 166.67 166.67 166.67 166.67 166.67 166.67 166.67 Configurations 4, 6 66.67 83.33 83.33 100 133.33 166.67 166.67 166.67 166.67 166.67 166.67 166.67 Configurations 1, 5 50 66.67 66.67 83.33 100 133.33 133.33 166.67 166.67 166.67 166.67 166.67 Configuration 2 33.33 33.33 33.33 50 66.67 83.33 83.33 166.67 133.33 166.67 166.67 166.67 ERROR DETECTION AND CORRECTION The optional Error Detection and Correction (EDC) feature implemented in this device is used to ensure data integrity between the DDR SDRAM and the Sequential Flow Control (SFC) device. The EDC will correct single bit errors that are accessed from the DDR SDRAM. Multiple bit errors are not detected nor corrected. The EDC circuit uses a syndrome bit generator to generate 8 syndrome bits that will detect whether there are single bit errors in each data word. The EDC is enabled using the MIC[2:0] pins. When the EDC is enabled, the dynamics of the total usable memory in the DDR SDRAM and SFC operating frequency will vary. Table 6 shows how to enable or disable the EDC feature for the various memory configurations. TABLE 6 - ERROR DETECTION AND CORRECTION CONFIGURATION External Memory Characteristic External Pins MIC0 MIC1 MIC2 x64 off EDC 1 1 1 x64 on EDC 1 0 1 x36 off EDC 0 1 1 x36 on EDC 0 0 1 14 x32 off EDC 0 0 0 x32 on EDC 0 1 0 x16 off EDC 1 0 0 x16 on EDC 1 1 0 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES CONNECTING THE DDR SDRAM The memory interface of the sequential flow-control device is designed for seamless connection to the DDR SDRAM. The output signal names should be connected directly to it's corresponding input signal on the DDR SDRAM. There are three signals on the DDR SDRAM that must be tied to a static state: CKE, CS, and DM. Figure 3 and 4 are some examples of the memory interface connections for various density configurations. For information on DDR SDRAM layout recommendations, please see IDT application note AN-423. Sequential Flow-Control Device CK CK DQS[3:0] WE CAS RAS DQ[31:0] A[11:0] 4 CK CK DDR SDRAM 2M x 16 x 4 128M DQS[3:0] WE CAS RAS DQ[31:0] A[11:0] CKE DM[3:0] CS 6357 drw11 VCC 32 12 Figure 3. Memory Interface Connection (Single Chip) Sequential Flow-Control Device CK CK DQS[7:0] WE CAS RAS DQ[31:0] A[11:0] 8 4 CK CK DDR SDRAM 8M x 32 256M DQS[3:0] WE CAS RAS DQ[31:0] A[11:0] CKE DM[3:0] CS VCC 64 12 32 12 CK CK 4 DQS[3:0] WE CAS RAS 32 12 DQ[31:0] A[11:0] DM[3:0] CS 6357 drw12 VCC CKE Figure 4. Memory Interface Connection (Two Chip) 15 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES SETTING THE MEMORY INTERFACE SIGNALS The configurations listed in Figure 2a-2g can be programmed into the sequential flow-control device by using the MIC[2:0], MTYPE[1:0], and MSPEED. For information about these signals, please refer to the Signal Description section. Table 7 is a list that shows the settings for the different configurations. TABLE 7 - MEMORY CONFIGURATIONS SETTINGS MIC[2:0] Configuration 1 Configuration 2 Configuration 3 Configuration 4 Configuration 5 Configuration 6 Configuration 7 000 - EDC Off 010 - EDC On 001 - EDC Off 011 - EDC On 111 - EDC Off 101 - EDC On 110 - EDC Off 100 - EDC On 000 - EDC Off 010 - EDC On 110 - EDC Off 100 - EDC On 111 - EDC Off 101 - EDC On MTYPE[1:0] 00 - (4Mb x 32) 10 - (8Mb x 32) 01 - (8Mb x 16) 11 - (16Mb x 16) 00 - (4Mb x 32) 10 - (8Mb x 32) 00 - (4Mb x 32) 10 - (8Mb x 32) 01 - (8Mb x 16) 11 - (16Mb x 16) 01 - (8Mb x 16) 11 - (16Mb x 16) 01 - (8Mb x 16) 11 - (16Mb x 16) MSPEED 0 - 133MHz 1 - 166MHz 0 - 133MHz 1 - 166MHz 0 - 133MHz 1 - 166MHz 0 - 133MHz 1 - 166MHz 0 - 133MHz 1 - 166MHz 0 - 133MHz 1 -166MHz 0 - 133MHz 1 - 166MHz 16 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES TABLE 8 - DEVICE CONFIGURATION Signal Pins Static State ASYR ASYW BW[3:0] FSEL[1:0] 0 1 0 1 -- 00 01 10 11 0 1 0 1 0 1 0 1 -- 0 1 00 01 10 11 Configuration Read port configured in asynchronous mode Read port configured in synchronous mode Write port configured in asynchronous mode Write port configured in synchronous mode See Table 11 - Bus-Matching Configurations Programmable flag register offset value = 127 Programmable flag register offset value = 1,023 Programmable flag register offset value = 4,095 Programmable flag register offset value = 16,383 IDT Standard mode FWFT mode Depth expansion in FWFT mode Depth expansion in IDT Standard mode I/O voltage set to 2.5V levels I/O voltage set to 3.3V levels JTAG function is disabled JTAG function is enabled See Table 6 - EDC Configuration for description External memory interface clocks set to 133MHz External memory interface clocks set to 166MHz External memory configuration is: 4M x 32 External memory configuration is: 8M x 32 External memory configuration is: 8M x 16 External memory configuration is: 16M x 16 FUNCTIONAL DESCRIPTIONS MASTER RESET AND DEVICE CONFIGURATION During master reset the sequential flow-control configuration and settings are determined, this includes the following: 1. Synchronous or Asynchronous read and write port operation 2. Bus-width configuration 3. Default offset register values 4. IDT standard or first word fall through (FWFT) timing mode 5. Depth expansion in IDT standard or FWFT mode 6. I/O voltage set to 2.5V or 3.3V levels 7. JTAG function enabled or disabled 8. Configuration of the external memory interface The state of the configuration inputs during master reset will determine which of the above modes are selected. A master reset comprises of pulsing the MRS input pin from high to low for a period of time (tRS) with the configuration inputs held in their respective states. Table 8 summarizes the configuration modes available during master reset. These signals are described in detail in the signal description section. PROGRAMMABLE ALMOST EMPTY/ALMOST FULL FLAGS The SFC has a set of programmable flags (PAE/PAF) that can be used as an early indicator for the empty and full boundary conditions. These flags have an offset value (n, m) that will determine the almost empty and almost full boundary conditions. There are four default offset values selectable during master reset, these values are shown in Table 9, Default Programmable Flag Offsets. Offset values can also be programmed using the serial programming pins (SCLK, SI, and SWEN). The SFC has two internal offset registers that are used to store the specific offset value, one for the PAE and one for the PAF. The total number of bits (shown in Table 10, Number of Bits Required for Offset Registers) must be completely programmed to the offset registers. The serial programming sequence begins by writing data into the PAE register followed by the PAF register. See Figure 29, Serial Loading of Programmable Flag Registers for the associated timing diagram. The total number of bits required to program the offset registers will vary depending on the type of configuration that is shown in Figure 2a-2g, the bus-width selected, and whether EDC is used. The values of n, m are used such that the PAE will become active (LOW) when there are at least one to n words written in the device. Similarly PAF will become active (LOW) when there are at least D - M words or more in the device, where D is the density of the SFC. FWFT IDEM IOSEL JSEL MIC[2:0] MSPEED MTYPE[1:0] TABLE 9- DEFAULT PROGRAMMABLE FLAG OFFSETS FSEL1 0 0 1 1 FSEL0 0 1 0 1 Offset n,m 127 1,023 4,095 16,383 TABLE 10- NUMBER OF BITS REQUIRED FOR OFFSET REGISTERS Write Port Bus-Width Configuration 1 (128Mb) Configuration 1 (256Mb) Configuration 2 (128Mb) Configuration 2 (256Mb) Configuration 3 (256Mb) Configuration 3 (512Mb) Configuration 4 (256Mb) Configuration 4 (512Mb) Configuration 5 (256Mb) Configuration 5 (512Mb) Configuration 6 (384Mb) Configuration 6 (768Mb) Configuration 7 (512Mb) Configuration 7 (1Gb) EDC On 21 22 21 22 22 23 22 23 22 23 23 24 23 24 x36 EDC Off 22 23 22 23 23 24 22 23 23 24 23 24 24 25 EDC On 22 23 22 23 23 24 23 24 23 24 24 25 24 25 17 x18 EDC Off 23 24 23 24 24 25 23 24 24 25 24 25 25 26 EDC On 23 24 23 24 24 25 24 25 24 25 25 26 25 26 x9 EDC Off 24 25 24 25 25 26 24 25 25 26 25 26 26 27 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES SIGNAL DESCRIPTIONS INPUTS DATA INPUTS (D0 - D35) Data inputs for 36-bit wide data (D0 - D35), data inputs for 18-bit wide data (D0 - D17) or data inputs for 9-bit wide data (D0 - D8). CONTROLS MASTER RESET (MRS) A Master Reset is accomplished whenever the MRS input is toggled LOW then HIGH. This operation sets the internal read and write pointers to the first location of the RAM array. PAE will go LOW, PAF will go HIGH. If FWFT is LOW during Master Reset then the IDT Standard mode, along with EF and FF are selected. EF will go LOW and FF will go HIGH. If FWFT is HIGH, then the First Word Fall Through mode (FWFT), along with IR and OR, are selected. OR will go HIGH and IR will go LOW. All configuration control signals must be set prior to the LOW to HIGH transition of MRS. During a Master Reset, the output register is initialized to all zeroes. A Master Reset is required after power up, before a write operation can take place. MRS is an asynchronous function. See Figure 6, Master Reset and Initialization, for the relevant timing diagram. PARTIAL RESET (PRS) A Partial Reset is accomplished whenever the PRS input is toggled LOW then HIGH. As in the case of the Master Reset, the internal read and write pointers are set to the first location of the RAM array, PAE goes LOW, and PAF goes HIGH. Whichever mode is active at the time of Partial Reset, IDT Standard mode or First Word Fall Through, that mode will remain selected. If the IDT Standard mode is active, then FF will go HIGH and EF will go LOW. If the First Word Fall Through mode is active, then OR will go HIGH, and IR will go LOW. Following Partial Reset, all values held in the offset registers remain unchanged. The programming method (parallel or serial) currently active at the time of Partial Reset is also retained. The output register is initialized to all zeroes. PRS is asynchronous. A Partial Reset is useful for resetting the device during the course of operation, when reprogramming programmable flag offset settings may not be convenient. See Figure 7, Partial Reset, for the relevant timing diagram. ASYNCHRONOUS WRITE (ASYW) The write port can be configured for either synchronous or asynchronous mode of operation. If during Master Reset the ASYW input is LOW, then asynchronous operation of the write port will be selected. During asynchronous operation of the write port the WCLK input becomes WR input, this is the asynchronous write strobe input. A rising edge on WR will write data present on the data inputs into the sequential flow-control device (SFC). (WEN must be LOW when using the write port in asynchronous mode). When the write port is configured for asynchronous operation the device must be operating on IDT standard mode, FWFT mode is not permissable. The full flag (FF) and programmable almost full flag (PAF) operates in an asynchronous manner, that is, the full flag and PAF flag will be updated based in both a write operation and read operation. Note, if asynchronous mode is selected, FWFT is not permissible. Refer to Figure 24, Asynchronous Write and PAE flag - IDT Standard mode and Figure 25, Asynchronous Write and PAF flag - IDT Standard mode for relevant timing and operational waveforms. ASYNCHRONOUS READ (ASYR) The read port can be configured for either synchronous or asynchronous mode of operation. If during a Master Reset the ASYR input is LOW, then asynchronous operation of the read port will be selected. During asynchronous operation of the read port the RCLK input becomes RD input, this is the asynchronous read strobe input. A rising edge on RD will read data from the SFC via the output register and data output port. (REN must be tied LOW during asynchronous operation of the read port). The OE input provides three-state control of the Qn output bus, in an asynchronous manner. When the read port is configured for asynchronous operation the device must be operating on IDT standard mode, FWFT mode is not permissible if the read port is asynchronous. The Empty Flag (EF) and programmable almost empty flag (PAF) operates in an asynchronous manner, that is, the empty flag and PAE will be updated based on both a read operation and a write operation. Refer to Figure 23, Asynchronous Read and PAF flag - IDT Standard mode, Figure 26, Asynchronous Empty Boundary - IDT Standard mode, Figure 27, Asynchronous Full Boundary - IDT Standard mode,, and Figure 28, Asynchronous Read and PAE flag - IDT Standard mode, for relevant timing and operational waveforms. FIRST WORD FALL THROUGH (FWFT) During Master Reset, the state of the FWFT input determines whether the device will operate in IDT standard mode or First Word Fall Through (FWFT) mode. If, at the time of Master Reset, FWFT is LOW, then IDT Standard mode will be selected. This mode uses the Empty Flag (EF) to indicate whether or not there are any words present in the SFC. It also uses the Full Flag function (FF) to indicate whether or not the SFC has any free space for writing. In IDT Standard mode, every word read from the SFC, including the first, must be requested using the Read Enable (REN) and RCLK. If, at the time of Master Reset, FWFT is HIGH, then FWFT mode will be selected. This mode uses Output Ready (OR) to indicate whether or not there is valid data at the data outputs (Qn). It also uses Input Ready (IR) to indicate whether or not the SFC has any free space for writing. In the FWFT mode, the first word written to an empty SFC goes directly to Qn after three RCLK rising edges, REN = LOW is not necessary. Subsequent words must be accessed using the Read Enable (REN) and RCLK. WRITE STROBE AND WRITE CLOCK (WR/WCLK) If synchronous operation of the write port has been selected via ASYW, this input behaves as WCLK. A write cycle is initiated on the rising edge of the WCLK input. Data setup and hold times must be met with respect to the LOW-to-HIGH transition of the WCLK. It is permissible to stop the WCLK. Note that while WCLK is idle, the FF/IR, and PAF flags will not be updated. The Write and Read Clocks can either be independent or coincident. If asynchronous operation has been selected this input is WR (write strobe). Data is asynchronously written into the SFC via the Dn inputs whenever there is a rising edge on WR. In this mode the WEN input must be LOW. WRITE ENABLE (WEN) When the WEN input is LOW, data may be loaded into the SFC on the rising edge of every WCLK cycle if the device is not full. Data is stored in the RAM array sequentially and independently of any ongoing read operation. When WEN is HIGH, no new data is written in the SFC. 18 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES To prevent data overflow in the IDT Standard mode, FF will go LOW, inhibiting further write operations. Upon the completion of a valid read cycle, FF will go HIGH allowing a write to occur. The FF is updated by two WCLK cycles + tSKEW after the RCLK cycle. To prevent data overflow in the FWFT mode, IR will go HIGH, inhibiting further write operations. Upon the completion of a valid read cycle, IR will go LOW allowing a write to occur. The IR flag is updated by two WCLK cycles + tSKEW after the valid RCLK cycle. WEN is ignored when the SFC is full in either FWFT or IDT Standard mode. If asynchronous operation of the write port has been selected, then WEN must be held active. READ STROBE AND READ CLOCK (RD/RCLK) If synchronous operation of the read port has been selected via ASYR, this input behaves as RCLK. A read cycle is initiated on the rising edge of the RCLK input. Data can be read on the outputs, on the rising edge of the RCLK input. It is permissible to stop the RCLK. Note that while RCLK is idle, the EF/OR and PAE flags will not be updated. The Write and Read Clocks can be independent or coincident. If asynchronous operation has been selected this input is RD (Read Strobe). Data is asynchronously read from the SFC whenever there is a rising edge on RD. In this mode the REN and RCS inputs must be tied LOW. The OE input is used to provide asynchronous control of the three-state Qn outputs. WRITE CHIP SELECT (WCS) The WCS disables all Write data operations (data only) if it is held HIGH. To perform normal operations on the write port, the WCS must be enabled, held LOW. READ ENABLE (REN) When Read Enable is LOW, data is loaded from the RAM array into the output register on the rising edge of every RCLK cycle if the device is not empty. When the REN input is HIGH, the output register holds the previous data and then no new data is loaded into the output register. The data outputs Q0-Qn maintain the previous data value. In the IDT Standard mode, every word accessed at Qn, including the first word written to an empty cache, must be requested using REN provided that RCS is LOW. When the last word has been read from the SFC, the Empty Flag (EF) will go LOW, inhibiting further read operations. REN is ignored when the SFC is empty. Once a write is performed, EF will go HIGH allowing a read to occur. The EF flag is updated by two RCLK cycles + tSKEW after the valid WCLK cycle. Both RCS and REN must be active, LOW for data to be read out on the rising edge of RCLK. In the FWFT mode, the first word written to an empty SFC automatically goes to the outputs Qn, on the third valid LOW-to-HIGH transition of RCLK + tSKEW after the first write. REN and RCS do not need to be asserted LOW for the First Word to fall through to the output register. In order to access all other words, a read must be executed using REN and RCS. The RCLK LOW-to-HIGH transition after the last word has been read from the SFC, Output Ready (OR) will go HIGH with a true read (RCLK with REN = LOW;RCS = LOW), inhibiting further read operations. REN is ignored when the SFC is empty. If asynchronous operation of the Read port has been selected, then REN must be held active, (LOW). OUTPUT ENABLE (OE) When Output Enable is enabled (LOW), the parallel output buffers receive data from the output register. When OE is HIGH, the output data bus (Qn) goes into a high impedance state. During Master or a Partial Reset the OE is the only 19 input that can place the output bus Qn, into High-Impedance. During Reset the RCS input can be HIGH or LOW, it has no effect on the Qn outputs. READ CHIP SELECT (RCS) The Read Chip Select input provides synchronous control of the Read output port. When RCS goes LOW, the next rising edge of RCLK causes the Qn outputs to go to the Low-Impedance state. When RCS goes HIGH, the next RCLK rising edge causes the Qn outputs to return to HIGH Z. During a Master or Partial Reset the RCS input has no effect on the Qn output bus, OE is the only input that provides High-Impedance control of the Qn outputs. If OE is LOW the Qn data outputs will be Low-Impedance regardless of RCS until the first rising edge of RCLK after a Reset is complete. Then if RCS is HIGH the data outputs will go to HighImpedance. The RCS input does not effect the operation of the flags. For example, when the first word is written to an empty SFC, the EF will still go from LOW to HIGH based on a rising edge of RCLK, regardless of the state of the RCS input. Also, when operating the SFC in FWFT mode the first word written to an empty SFC will still be clocked through to the output register based on RCLK, regardless of the state of RCS. For this reason the user must take care when a data word is written to an empty SFC in FWFT mode. If RCS is disabled when an empty SFC is written into, the first word will fall through to the output register, but will not be available on the Qn outputs which are in HIGH-Z. The user must take RCS active LOW to access this first word, place the output bus in LOW-Z. REN must remain disabled HIGH for at least one cycle after RCS has gone LOW. A rising edge of RCLK with RCS and REN active LOW, will read out the next word. Care must be taken so as not to lose the first word written to an empty SFC when RCS is HIGH. See Figure 15 for Read Chip Select. If asynchronous operation of the Read port has been selected, then RCS must be held active, (tied LOW). OE provides three-state control of Qn. BUS-MATCHING (BM[3:0]) These pins are used to define the input and output bus widths. During Master Reset, the state of these pins is used to configure the device bus sizes. All flags will operate on the word/byte size boundary as defined by the selection of bus width. See Figures 22-25 for Bus-Matching Configurations. See Table 11, BusMatching Configurations for the available configurations. TABLE 11 - BUS-MATCHINGS BM0 0 1 1 1 1 1 1 1 1 BM1 0 0 0 1 1 0 0 1 1 BM2 0 0 1 0 1 0 1 0 1 BM3 1 1 1 1 1 0 0 0 0 Read Bus Width x36 x18 x9 x36 x36 x18 x9 x18 x9 Write Bus Width x36 x36 x36 x18 x9 x18 x18 x9 x9 FLAG SELECT (FSEL[1:0]) During master reset, these inputs will select one of four default values for the programmable flags PAE and PAF. The selected value (listed in Table 12 MTYPE[1:0] Configurations) will apply to both PAE and PAF offset. IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES MEMORY CONFIGURATION (MIC[2:0]) These signals enable the EDC feature of the device. See Table 6, Error Detection and Correction (EDC) for more information. MEMORY SPEED (MSPEED) This pin is used to determine the memory interface clock speed (CK and CK) for the external memory used. If MSPEED is HIGH, external memory CK and CK will be operating at 166MHz. If MSPEED is LOW, then the external memory CK and CK will be operating at 133MHz. MASTER CLOCK (MCLK) 33MHz reference clock used to generate CK and CK for external memory interface. MEMORY TYPE (MTYPE[1:0]) These signals select the density configuration of the external DDR SDRAM used. See Table 12, for selection of the memory density configuration. modes. See Figure 29, Loading of Programmable Flag Registers, for the timing diagram. I/O VDDQ SELECT (IOSEL) This input determines whether the inputs and outputs will tolerate a 2.5V or 3.3V voltage signals. If IOSEL is HIGH, then all I/Os will be 3.3V levels. If IOSEL is LOW, then all I/Os will be 2.5V levels. JTAG SELECT (JSEL) This input determines whether the JTAG port will be activated or deactivated. If JSEL is HIGH, then the JTAG port is activated and the associated JTAG pins (TCK, TDI, TDO, TMS) are used for the boundary-scan function. If JSEL is LOW, the JTAG port is disabled and the serial programming pins (SCLK, SI, SO) will be used to program and read the offset register values for PAE and PAF. See Figure 29 and 30, Serial Loading and Reading of Programmable Registers for information on how to program the registers. OUTPUTS TABLE 12 - MTYPE[1:0] CONFIGURATIONS Density Configurations 4M x 32 MTYPE0 MTYPE1 0 0 8M x 32 0 1 8M x 16 1 0 16M x 16 1 1 FULL FLAG/INPUT READY (FF/IR) This is a dual purpose pin. In IDT Standard mode, the Full Flag (FF) function is selected. When the SFC is full, FF will go LOW, inhibiting further write operations. When FF is HIGH, the SFC is not full. If no reads are performed after a reset (either MRS or PRS), FF will go LOW See Figure 12, Full Boundary - IDT Standard Mode, for the relevant timing information. In FWFT mode, the Input Ready (IR) function is selected. IR goes LOW when memory space is available for writing in data. When there is no longer any free space left, IR goes HIGH, inhibiting further write operations. If no reads are performed after a reset (either MRS or PRS), IR will go HIGH see Figure 9 Write First Word Cycles - FWFT Mode, for the relevant timing information. The IR status not only measures the contents of the SFC memory, but also counts the presence of a word in the output register. Thus, in FWFT mode, the total number of writes necessary to de-assert IR is one greater than needed to assert FF in IDT Standard mode. FF/IR is synchronous and updated on the rising edge of WCLK. FF/IR are double register-buffered outputs. EMPTY FLAG (EF/OR) This is a dual purpose pin. In the IDT Standard mode, the Empty Flag (EF) function is selected. When the SFC is empty, EF will go LOW, inhibiting further read operations. When EF is HIGH, the SFC is not empty. Figure 10, Empty Boundary - IDT Standard Mode for the relevant timing information. In FWFT mode, the Output Ready (OR) function is selected. OR goes LOW at the same time that the first word written to an empty SFC appears valid on the outputs. OR stays LOW after the RCLK LOW to HIGH transition that shifts the last word from the SFC to the outputs. OR goes HIGH only with a true read (RCLK with REN = LOW). The previous data stays at the outputs, indicating the last word was read. Further data reads are inhibited until OR goes LOW again. See Figure 11, Empty Boundary (FWFT Mode), for the relevant timing information. EF/OR is synchronous and updated on the rising edge of RCLK. In IDT Standard mode, EF is a double register-buffered output. In FWFT mode, OR is a triple register-buffered output. PROGRAMMABLE ALMOST-FULL FLAG (PAF) The Programmable Almost-Full flag (PAF) will go LOW when the SFC reaches the almost-full condition. In IDT Standard mode, if no reads are performed after reset (MRS), PAF will go LOW after (D - m) words are written 20 DEPTH EXPANSION MODE SELECT (IDEM) This select pin is used for depth expansion configuration in IDT Standard mode. If this pin is tied HIGH, then the FF/IR signal will be inverted to provide a seamless depth expansion interface. If this pin is tied LOW, the depth expansion in IDT Standard mode will be deactivated. For details on depth expansion configuration, see Figure 34, Depth Expansion Configuration in IDT Standard Mode and Figure 35, Depth Expansion Configuration in FWFT Mode. SERIAL READ ENABLE (SREN) The serial read enable input is an enable used for reading the value of the programmable offset registers. By setting the JSEL pin to LOW, the serial data output (SO) and serial clock (SCLK) signals can be used with SREN to program the offset registers. When SREN is LOW, data at the SO can be read from the offset register, one bit for each LOW-to-HIGH transition of SCLK. When serial read enable is HIGH, the reading of the offset registers will stop. SREN must be kept LOW in order to read the entire contents of the scan out register. If at any point SREN is toggled HIGH, the read pointer of the offset registers will reset to the first location. The next time SREN is enabled the first contents in the offset register will be read back. Serial read enable functions the same way in both IDT Standard and FWFT modes. See Figure 30, Reading of Programmable Flag Registers, for the timing diagram. SERIAL WRITE ENABLE (SWEN) The serial write enable input is an enable used for serial programming of the programmable offset registers. By setting the JSEL pin to LOW, the serial input (SI) and serial clock (SCLK) signals can be used with SWEN to program the offset registers. When SWEN is LOW, data at the SI input are loaded into the offset register, one bit for each LOW-to-HIGH transition of SCLK. When SWEN is HIGH, the offset registers retain the previous settings and no offsets are loaded. Serial write enable functions the same way in both Standard IDT and FWFT IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES to the SFC. See Figure 22, Synchronous PAF Flag - IDT Standard Mode and FWFT Mode, for the relevant timing information. If asynchronous PAF configuration is selected, the PAF is asserted LOW on the LOW-to-HIGH transition of the Write Clock (WCLK). PAF is reset to HIGH on the LOW-to-HIGH transition of the Read Clock (RCLK). If synchronous PAF configuration is selected, the PAF is updated on the rising edge of WCLK. PROGRAMMABLE ALMOST-EMPTY FLAG (PAE) The Programmable Almost-Empty flag (PAE) will go LOW when the SFC reaches the almost-empty condition. In IDT Standard mode, PAE will go LOW when there are n words or less in the SFC. The offset "n" is the empty offset value. The default setting for this value is in Table 8, Device Configuration. In FWFT mode, the PAE will go LOW when there are n+1 words or less in the SFC. See Figure 21, Synchronous PAE Flag - IDT Standard Mode and FWFT Mode, for the relevant timing information. If asynchronous PAE configuration is selected, the PAE is asserted LOW on the LOW-to-HIGH transition of the Read Clock (RCLK). PAE is reset to HIGH on the LOW-to-HIGH transition of the Write Clock (WCLK). If synchronous PAE configuration is selected, the PAE is updated on the rising edge of RCLK. DATA OUTPUTS (Q0-Q35) (Q0-Q35) are data outputs for 36-bit wide data, (Q0 - Q17) are data outputs for 18-bit wide data or (Q0-Q8) are data outputs for 9-bit wide data. MEMORY CLOCK OUTPUT (CK) These signals are to be connected to the external DDR SDRAM's clock input. MEMORY CLOCK OUTPUT INVERTED (CK) These signals are to be connected to the external DDR SDRAM's differential clock input. MEMORY BANK ADDRESS INPUT BIT (BA[1:0]) These signals are to be connected to the external DDR SDRAM's bank address input bits. MEMORY COLUMN ADDRESS STROBE (CAS) These signals are to be connected to the external DDR SDRAM's column address strobe input. MEMORY ADDRESS BUS (A[12:0]) These signals are to be connected to the external DDR SDRAM's address bus. MEMORY WRITE ENABLE (WE) These signals are to be connected to the external DDR SDRAM's write enable. MEMORY ROW ADDRESS STROBE (RAS) These signals are to be connected to the external DDR SDRAM's row address strobe input. BI-DIRECTIONAL I/O MEMORY DATA INPUTS/OUTPUTS DQ[63:0] These signals are to be connected to the external DDR SDRAM's data input bus. MEMORY DATA STROBE OUTPUT DQS[7:0] These signals are to be connected to the external DDR SDRAM's data strobe inputs. 21 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES ABSOLUTE MAXIMUM RATINGS Symbol VTERM TSTG TJMAX IOUT Rating Terminal Voltage with respect to GND Storage Temperature Maximum Junction Temp. DC Output Current Com'l & Ind'l -0.5 to +3.6(2) -55 to +125 150 -50 to +50 Unit V CAPACITANCE (TA = +25C, f = 1.0MHz) Symbol CIN (2,3) Parameter(1) Input Capacitance Output Capacitance Conditions VIN = 0V VOUT = 0V Max. 10 (3) Unit pF pF C C mA COUT(1,2) 10 NOTES: 1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. 2. Compliant with JEDEC JESD8-5. VCC terminal only. NOTES: 1. With output deselected, (OE VIH). 2. Characterized values, not currently tested. 3. CIN for Vref is 20pF. PACKAGE THERMAL DATA Symbol Parameter Junction to case thermal resistance Junction to air thermal resistance airflow @ 0m/s @ 1m/s @ 2m/s @ 3m/s @ 4m/s @ 5m/s MSL Moisture sensitivity level 27.4 22.8 20.3 19.5 18.2 17.8 3 Industrial/ Commercial 3.8 Unit C/W C/W JC JA RECOMMENDED DC OPERATING CONDITIONS Symbol VCC VDDQ GND VIH VIL VREF TA TA Parameter Supply Voltage Output Rail Voltage for I/Os Supply Ground Input High Voltage Input Low Voltage Voltage Reference Input Operating Temperature (Commercial) Operating Temperature (Industrial) @ 3.3V @ 2.5V @ 3.3V @ 2.5V Min. 2.375 2.375 0 2.0 1.7 -- -0.3 1.15 0 -40 Typ. 2.5 -- 0 -- -- -- -- 1.25 -- -- Max. 2.625 3.45 0 5.5 3.45 0.8 0.7 1.35 70 85 Unit V V V V V V V V C C 22 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES DC ELECTRICAL CHARACTERISTICS (Commercial: VCC = 2.5V 0.125V, TA = 0C to +70C;Industrial: VCC = 2.5V 0.125V, TA = -40C to +85C) Symbol ILI(1) ILO(2) VOH1 VOH2 VOL1 VOL2 IOH1 IOH2 IOL1 IOL2 ICC(5) ISB Parameter Input leakage current Output leakage current Read/Write interface output logic "1" voltage Memory interface output logic "1" voltage Read/Write interface output logic "0" voltage Memory interface output logic "0" voltage Read/Write interface output high current (source current) Read/Write interface output low current (sink current) Read/Write interface output low current (sink current) Memory interface output low current (sink current) Active VCC current Standby VCC current VDDQ = 3.3V VDDQ = 2.5V VDDQ = 3.3V VDDQ = 2.5V Min. -10 -10 VDDQ - 0.4 VDDQ - 0.4 1.46 -- -- -- -8 -16 8 16 -- -- Typ. -- -- -- -- -- -- -- -- -- -- -- -- 380 -- Max. 10 10 -- -- 2.8 0.4 0.4 1.04 -- -- -- -- 1300 50 Unit mA mA V V V V V V mA mA mA mA mA mA NOTES: 1. Measurements with 0.4 VIN VCC. 2. OE VIH, 0.4 VOUT VCC. 3. Tested with outputs open (IOUT = 0). 4. RCLK and WCLK toggle at 20MHz and data inputs switch at 10MHz. 5. Typical values represent frquency = 0MHz. Maximum values represent frequency = 166MHz. 6. This is the formula used for calculating ICC: P = C x V2 x f x D x BW ICC = P V f C V D BW = = = = = operating frequency capacitive load VCC voltage duty cycle bus width 23 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES 2.5V AC TEST CONDITIONS Input Pulse Levels Input Rise/Fall Times Input Timing Reference Levels Output Reference Levels GND to 2.5V 1ns VCC/2 VDDQ/2 AC TEST LOADS VDDQ/2 50 I/O Z0 = 50 6357 drw13 Figure 5a. AC Test Load 3.3V AC TEST CONDITIONS Input Pulse Levels Input Rise/Fall Times Input Timing Reference Levels Output Reference Levels GND to 3.0V 3ns 1.5V 1.5V 6 tCD (Typical, ns) 5 4 3 2 1 20 30 50 80 100 Capacitance (pF) 200 6357 drw13a Figure 5b. Lumped Capacitive Load, Typical Derating 24 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES AC ELECTRICAL CHARACTERISTICS(1) SYNCHRONOUS TIMING (Commercial: VCC = 2.5V 5%, TA = 0C to +70C;Industrial: VCC = 2.5V 5%, TA = -40C to +85C) Commercial IDT72T6360L6 Symbol fS tA tCLK tCLKH tCLKL tDS tDH tENS tENH tRS tRSU tRSH tPL tRSF tOHZ tOE fMC tMCYC tMCKH tMCKL fSC tSCLK tSCLKH tSCLKL tSDS tSDH tSENS tSENH tASO tWFFs tREFs tPAFs tPAEs tSKEW1 tSKEW2 tWCSS tWCSH fC1 fC2 tCK1 tCK2 tCKH1 tCKH2 tCKL1 tCKL2 Parameter Synchronous Clock Cycle Frequency Data Access Time Clock Cycle Time Clock High Time Clock Low Time Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Reset Pulse Width Reset Setup Time Reset Hold Time Reset to PLL Lock Reset to Flag and Output Output enable to High-Z Output Enable Valid Master Clock Cycle Frequency Master Clock Cycle Time Master Clock Cycle HIGH Master Clock Cycle LOW Serial Clock Cycle Frequency Serial Clock Cycle Serial Clock HIGH Serial Clock LOW Serial Data Setup Serial Data Hold Serial Enable Setup Serial Enable Hold Serial Output Data Access Time Write Clock to Synchronous FF/IR Read Clock to Synchronous EF/OR WCLK to Synchronous PAF RCLK to Synchronous PAE Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR Skew time between RCLK and WCLK for PAE/PAF WCS Setup Time WCS Hold Time Memory Clock Cycle Frequency at 166MHz Memory Clock Cycle Frequency at 133MHz Memory Clock Cycle Time at 166MHz Memory Clock Cycle Time at 133MHz Memory Clock Cycle HIGH at 166MHz Memory Clock Cycle HIGH at 133MHz Memory Clock Cycle LOW at 166MHz Memory Clock Cycle LOW at 133MHz Min. -- 1 6 2.7 2.7 2 0.5 2 0.5 200 15 10 20 -- 1 1 32 29.4 0.45 0.45 -- 100 45 45 15 5 5 5 -- -- -- -- -- 4 5 2 0.5 160 128 6.2 7.8 0.45 0.45 0.45 0.45 Max. 166 4 -- -- -- -- -- -- -- -- -- -- -- 15 4 4 34 31.3 0.55 0.55 10 -- -- -- -- -- -- -- 20 4 4 4 4 -- -- -- -- 170 136 5.9 7.3 0.55 0.55 0.55 0.55 Com'l & Ind'l(2) IDT72T6360L7-5 Min. -- 1 7.5 3.5 3.5 2.5 0.5 2.5 0.5 200 15 10 20 -- 1 1 32 29.4 0.45 0.45 -- 100 45 45 15 5 5 5 -- -- -- -- -- 5 7 2.5 0.5 -- 128 -- 7.8 -- 0.45 -- 0.45 Max. 133 5 -- -- -- -- -- -- -- -- -- -- -- 15 5 5 34 31.3 0.55 0.55 10 -- -- -- -- -- -- -- 20 5 5 5 5 -- -- -- -- -- 136 -- 7.3 -- 0.55 -- 0.55 Unit MHz ns ns ns ns ns ns ns ns ns ns ns s ns ns ns MHz ns tMCYC tMCYC MHz ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns MHz MHz ns ns tCK1 tCK2 tCK1 tCK2 NOTES: 1. All AC timings apply to both Standard IDT mode and First Word Fall Through mode. 2. Industrial temperature range product for the 7.5ns speed grade is available as a standard device. All other speed grades are available by special order. 25 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES AC ELECTRICAL CHARACTERISTICS ASYNCHRONOUS TIMING (Commercial: VCC = 2.5V 5%, TA = 0C to +70C;Industrial: VCC = 2.5V 5%, TA = -40C to +85C) Commercial IDT72T6360L6 Symbol fA tAa tCYC tCYCH tCYCL tFFa tEFa tPAFa tPAEa tRPE Parameter Asynchronous Clock Cycle Frequency Data Access Time Cycle Time Cycle HIGH Time Cycle LOW Time Rising Edge to FF Rising Edge to EF Rising Edge to PAF Rising Edge to PAE Read Pulse after EF HIGH Min. -- 0.6 10 4.5 4.5 -- -- -- -- 8 Max. 100 8 -- -- -- 8 8 8 8 -- Com'l & Ind'l(2) IDT72T6360L7-5 Min. -- 0.6 12 5 5 -- -- -- -- 10 Max. 83 10 -- -- -- 10 10 10 10 -- Unit MHz ns ns ns ns ns ns ns ns ns NOTES: 1. All AC timings apply to both Standard IDT mode and First Word Fall Through mode. 2. Industrial temperature range product for the 7.5ns speed grade is available as a standard device. All other speed grades are available by special order. 26 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES MRS REN tRS tRSU tRSU tRH tRH tRH tRH tRSF WEN tRSU SREN tRSU SWEN EF OR FF IR CK CK Q[35:0] tRSU FWFT Mode IDT Standard Mode If IDT mode is selected tRSF If FWFT mode is selected tPL If IDT mode is selected tPL If FWFT mode is selected tPL The clock may not be locked to the required operation frequency before tPL tPL The clock may not be locked to the required operation frequency before tPL If OE = HIGH If OE = LOW FWFT tRSU Synchronous read port selected Asynchronous read port selected ASYR tRSU Synchronous write port selected Asynchronous write port selected ASYW tRSU 3.3V I/O voltage selected 2.5V I/O voltage selected IOSEL PAF tRSF tRSF PAE tRSU Depth Expansion in IDT Standard Mode Depth Expansion in FWFT Standard Mode 6357 drw20 IDEM NOTE: 1. For other signals that are latched during master reset, refer to Master Reset and Device Configuration section. Symbol tRS tRSU tRSH tPL tRSF Parameter Reset Pulse Width Reset Setup Time Reset Hold Time Reset to PLL Lock Reset to Flag and Output Min. 200 15 10 20 -- Max. -- -- -- -- 15 Unit ns ns ns s ns Figure 6. Master Reset and Initialization 27 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES tRS PRS tRSU REN tRSU WEN tRSU SREN tRSU SWEN tRSF EF OR FF IR Q[35:0] tRSF PAF tRSF PAE 6357 drw21 tRH tRH tRH tRH If IDT mode is selected tRSF If FWFT mode is selected tRSF If IDT mode is selected tRSF If FWFT mode is selected If OE = HIGH If OE = LOW Symbol tRS tRSU tRSH tPL tRSF Parameter Reset Pulse Width Reset Setup Time Reset Hold Time Reset to PLL Lock Reset to Flag and Output Min. 200 15 10 20 -- Max. -- -- -- -- 15 Unit ns ns ns s ns Figure 7. Partial Reset 28 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION WCLK tENS WEN tENS D[35:0] tENH Word 1 Word 2 COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES tENH Word 0 tSKEW1 RCLK REN tREFs EF tA Q[35:0] Word 0 1 2 tENS tENH tREFs tA Word 1 tA Word 2 6357 drw22 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. Figure 8. Write First Word Cycles - IDT Standard Mode WCLK tENS WEN tENS D[35:0] tENH Word 1 Word 2 tENH Word 0 tSKEW1 RCLK REN tREFs OR tA Q[35:0] Word 0 1 2 3 tENS tENH tREFs tA Word 1 tA Word 2 6357 drw23 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = HIGH, ASYR = HIGH, and ASYW = HIGH. Figure 9. Write First Word Cycles - FWFT Mode 6ns Min. Max. 5 -- 5 -- 1 4 4 -- -- 4 7-5ns Min. Max. 5 -- 5 -- 1 5 5 -- -- 5 Symbol tSENS tSENH tA tSKEW1 tREFs Parameter Serial Enable Setup Serial Enable Hold Data Access Time Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR Read Clock to Synchronous EF/OR 29 Unit ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION tCLKH tCLK tCLKL tENS NO OPERATION NO OPERATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES RCLK tENS tENH 1 2 tENH tENS tENH REN tREF tREF tA Last Word tOHZ tOLZ Last Word Word 0 tREF EF tA tA Word 1 Q[35:0] OE WCLK tENS tOE tSKEW1 (1) tENH tENS tENH WEN D[35:0] tDH tDS Word 0 tDS Word 1 6357 drw24 tDH NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. Figure 10. Empty Boundary - IDT Standard Mode RCLK REN 1 2 3 tREFs OR tA Q[35:0] Last Word - 3 tREFs tA Last Word - 2 tA Last Word - 1 Last Word tA Word 0 tSKEW1 WCLK tENS WEN tDS D[35:0] Word 0 tENH tDH 6357 drw25 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = HIGH, ASYR = HIGH, and ASYW = HIGH. Figure 11. Empty Boundary - FWFT Mode 6ns Symbol tCLK tCLKH tCLKL tDS tDH tENS tENH tA tREFs tSKEW1 Parameter Clock Cycle Time Clock High Time Clock Low Time Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Data Access Time Read Clock to Synchronous EF/OR Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR 30 Min. 6 2.7 2.7 2 0.5 2 0.5 1 -- 4 Max. -- -- -- -- -- -- -- 4 4 -- 7-5ns Min. Max. 7.5 -- 3.5 -- 3.5 -- 2.5 -- 0.5 -- 2.5 -- 0.5 -- 1 5 -- 5 5 -- Unit ns ns ns ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION WCLK tENS WEN tDS D[35:0] WD-1 1 2 COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES tENH tSKEW1 tDH WD tWFFs FF tWFFs RCLK tENS REN tA Q[35:0] Previous Word in Register Word 0 tA Word 1 tA Word 2 tA Word 3 NOTES: 1. tSKEW1 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that FF will go HIGH after one WCLK cycle (plus tWFFs). If tSKEW1 is not met, then FF de-assertion may be delayed one extra WCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. 6357 drw26 Figure 12. Full Boundary - IDT Standard Mode 1 2 WCLK tENS WEN tDS D[35:0] WD-1 tENH tSKEW1 tDH WD tWFFs IR tWFFs RCLK tENS REN tA Q[35:0] Word 0 Word 1 tA Word 2 tA Word 3 tA Word 4 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: RCS = LOW, WCS = LOW, BM[3:0] = 1000, FWFT = HIGH, ASYR = HIGH, and ASYW = HIGH. 6357 drw27 Figure 13. Full Boundary - FWFT Mode 6ns Max. -- -- -- -- 4 4 -- 7-5ns Min. Max. 2.5 -- 0.5 -- 2.5 -- 0.5 -- 1 5 -- 5 5 -- Symbol tDS tDH tENS tENH tA tWFFs tSKEW1 Parameter Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Data Access Time Write Clock to Synchronous FF/IR Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR 31 Min. 2 0.5 2 0.5 1 -- 4 Unit ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION RCLK REN tA Q[35:0] Word 1 Word 2 COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES tA Word 3 tA Word 4 Word 4 tOHZ OE NOTE: 1. Settings: RCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. tOE 6357 drw28 Figure 14. Output Enable RCLK tENH REN tA Q[35:0] Word 1 Word 2 tA Word 3 tA tRCSLZ Word 4 tRCSHZ tA Word 4 tENS RCS NOTE: 1. Settings: OE = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. tENS 6357 drw29 Figure 15. Read Chip Select WCLK tENS WEN tDS D[35:0] Word 0 tDH Word 1 Word 2 tWCSS WCS tWCSH 6357 drw30 NOTE: 1. Settings: BM[3:0] = 1000, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. Figure 16. Write Chip Select 6ns Min. Max. 2 -- 0.5 -- 2 -- 0.5 -- 1 4 1 4 1 4 2 -- 0.5 -- 32 7-5ns Min. Max. 2.5 -- 0.5 -- 2.5 -- 0.5 -- 1 5 1 5 1 5 2.5 -- 0.5 -- Symbol tDS tDH tENS tENH tA tOHZ tOE tWCSS tWCSH Parameter Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Data Access Time Output enable to High-Z Output Enable Valid WCS Setup Time WCS Hold Time Unit ns ns ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION WCLK tENS tENH WEN tDS D[35:0] tDH COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES Word 0 tSKEW1 RCLK REN tREFs EF tA Q[17:0] Previous Word in Register D[35:18] 1 2 tENS tENH tREFs tA Word 0 D[17:0] Word 0 D[35:18] NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1011, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. 6357 drw31 Figure 17. Bus-Matching Configuration - x36 In to x18 Out - IDT Standard Mode WCLK tENS tENH WEN tDS D[35:0] tDH Word 0 tSKEW1 RCLK REN tREFS EF tA Q[8:0] Previous Word in Register D[35:27] 1 2 tENS tREFS tA Word 0 D[8:0] tA Word 0 D[17:9] tA Word 0 D[26:18] Word 0 D[35:27] 6358 drw32 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1111, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. Figure 18. Bus-Matching Configuration - x36 In to x9 Out - IDT Standard Mode 6ns Symbol tDS tDH tENS tENH tA tREFs tSKEW1 Parameter Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Data Access Time Read Clock to Synchronous EF/OR Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR 33 Min. 2 0.5 2 0.5 1 -- 4 Max. -- -- -- -- 4 4 -- 7-5ns Min. Max. 2.5 -- 0.5 -- 2.5 -- 0.5 -- 1 5 -- 5 5 -- Unit ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION WCLK tENS WEN tDS D[17:0] tDH tDS tDH tENH COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES Word 0 Q[17:0] Word 0 Q[17:0] tSKEW1 RCLK REN tREFS EF tA Q[35:0] Previous Word in Register Word 0 1 2 tENS tENH tREFS NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1001, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. 6357 drw33 Figure 19. Bus-Matching Configuration - x18 In to x36 Out - IDT Standard Mode WCLK tENS WEN tDS D[8:0] tDH Word 0 Q[17:9] Word 0 Q[26:18] Word 0 Q[35:27] tENH Word 0 Q[8:0] tSKEW1 RCLK 1 2 3 tENS REN tREFS EF tENH tREFS tA Q[35:0] Previous Word in Register Word 0 6357 drw34 NOTES: 1. tSKEW1 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH after one RCLK cycle (plus tREFs). If tSKEW1 is not met, then EF de-assertion may be delayed one extra RCLK cycle. 2. Settings: OE = LOW, RCS = LOW, WCS = LOW, BM[3:0] = 1101, FWFT = LOW, ASYR = HIGH, and ASYW = HIGH. Figure 20. Bus-Matching Configuration - x9 In to x36 Out - IDT Standard Mode 6ns Symbol tDS tDH tENS tENH tA tREFs tSKEW1 Parameter Data Setup Time Data Hold Time Enable Setup Time Enable Hold Time Data Access Time Read Clock to Synchronous EF/OR Skew time between RCLK and WCLK for EF/OR and FF/IR in SDR 34 Min. 2 0.5 2 0.5 1 -- 4 Max. -- -- -- -- 4 4 -- 7-5ns Min. Max. 2.5 -- 0.5 -- 2.5 -- 0.5 -- 1 5 -- 5 5 -- Unit ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION WCLK tENH WEN tDS D[35:0] PAE tDH COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES Word n + 1 n words or less in Memory (2) n + 1 words or less in Memory (2) n + 1 words or more in Memory (2) n + 2 words or more in Memory (2) tSKEW2 RCLK REN 1 tPAEs 2 1 tPAEs 2 tENS tENH tA Q[35:0] Previous Word in Register Word 0 6357 drw35 NOTES: 1. tSKEW2 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that PAE will go HIGH after one RCLK cycle (plus tPAEs). If tSKEW2 is not met, then PAE de-assertion may be delayed one extra RCLK cycle. 2. n = PAE offset, see Table10 for information on setting PAE offset values. 3. Settings: OE = LOW, RCS = LOW, BM[3:0] = 1000, ASYR = HIGH, and ASYW = HIGH. Figure 21. Synchronous PAE Flag - IDT Standard Mode and FWFT Mode WCLK tDH WEN tDS D[35:0] Word D - (m + 1) 1 2 1 2 tDH Word D - m tPAFs PAF D - (m + 1) words or less in Memory D - m words or more in Memory tPAFs tSKEW2 RCLK tENS REN tA Q[35:0] Previous Word in Register Word 0 6357 drw36 tENH NOTES: 1. tSKEW2 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that PAF will go HIGH after one RCLK cycle (plus tPAFs). If tSKEW2 is not met, then PAF de-assertion may be delayed one extra RCLK cycle. 2. m = PAF offset, D = density of SFC, see Table10 for information on setting PAF offset values. 3. Settings: OE = LOW, RCS = LOW, BM[3:0] = 1000, ASYR = HIGH, and ASYW = HIGH. Figure 22. Synchronous PAF Flag - IDT Standard Mode and FWFT Mode 6ns Symbol tDS tDH tENH tA tPAFs tPAEs tSKEW2 Parameter Data Setup Time Data Hold Time Enable Hold Time Data Access Time WCLK to Synchronous PAF RCLK to Synchronous PAE Skew time between RCLK and WCLK for PAE/PAF Min. 2 0.5 0.5 1 -- -- 5 Max. -- -- -- 4 4 4 -- 7-5ns Min. Max. 2.5 -- 0.5 -- 0.5 -- 1 5 -- 5 -- 5 7 -- Unit ns ns ns ns ns ns ns 35 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES RD tAa Q[35:0] Word D - (m - 2) tAa Word D - (m - 1) Word D - m tAa Word D - (m + 1) tPAFa PAF (D - m) words or more in Memory D - (m + 1) words or less in Memory NOTES: 1. m = PAF offset, see Table10 for information on PAF offset values. D = density of SFC. 2. Settings: OE = LOW, RCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = LOW, and ASYW = LOW. 3. Asynchronous read is available in IDT standard mode only. 6357 drw37 Figure 23. Asynchronous Read and PAF Flag - IDT Standard Mode WR tDS D[35:0] PAE tDH tDS Word n tDH tDS tDH Word n - 1 Word n + 1 tPAEa n words or less in Memory (1) n + 1 words or more in Memory (1) 6357 drw38 NOTES: 1. n = PAE offset, see Table10 for information on PAE offset values. 2. Settings: WCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = LOW, and ASYW = LOW. 3. Asynchronous read is available in IDT standard mode only. Figure 24. Asynchronous Write and PAE Flag - IDT Standard Mode WR tDS D[35:0] PAF tDH tDS tDH tDS tDH Word D - (m + 2) Word D - (m + 1) Word D - m tPAFa D - (m + 1) words or less in Memory D - m words or more in Memory 6357 drw39 NOTES: 1. m = PAF offset, see Table10 for information on PAF offset values. D = density of SFC. 2. Settings: WCS = LOW, BM[3:0] = 1000, FWFT = LOW, ASYR = LOW, and ASYW = LOW. 3. Asynchronous read is available in IDT standard mode only. Figure 25. Asynchronous Write and PAF Flag - IDT Standard Mode 6ns Symbol tDS tDH tAa tPAFa Parameter Data Setup Time Data Hold Time Data Access Time Rising Edge to PAF 36 Min. 2 0.5 0.6 -- Max. -- -- 8 8 7-5ns Min. Max. 2.5 -- 0.5 -- 0.6 10 -- 10 Unit ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION tCYC tCYCH tCYCL COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES WR tDS tDH tDS tDH D[35:0] RD Word 0 Word 1 tRPE tAa tAa Word 0 Word 1 Q[35:0] EF Previous word in register tEFa tEFa 6357 drw40 NOTES: 1. Settings: OE = LOW, RCS = LOW, WCS = LOW, FWFT = LOW, ASYR = LOW, and ASYW = LOW. 2. Asynchronous read is available in IDT standard mode only. Figure 26. Asynchronous Empty Boundary - IDT Standard Mode WR tDS tDH D[35:0] RD WD tAa Q[35:0] tFFa Previous word in register Word 0 tFFa 6357 drw41 FF NOTES: 1. Settings: OE = LOW, RCS = LOW, WCS = LOW, FWFT = LOW, ASYR = LOW, and ASYW = LOW. 2. Asynchronous read is available in IDT standard mode only. Figure 27. Asynchronous Full Boundary - IDT Standard Mode RD tAa tAa Word n - 2 Word n - 1 tAa Word n Q[35:0] PAE Word n - 3 tPAEa n words or less in Memory (1) n words or more in Memory (1) 6357 drw42 NOTES: 1. n = PAE offset, see Table10 for information on PAE offset values. 2. Asynchronous read is available in IDT standard mode only. Figure 28. Asynchronous Read and PAE Flag - IDT Standard Mode 6ns Symbol tAa tCYC tCYCH tCYCL tDH tDS tEFa tFFa tPAEa tRPE Parameter Data Access Time Cycle Time Cycle HIGH Time Cycle LOW Time Data Hold Time Data Setup Time Rising Edge to EF Rising Edge to FF Rising Edge to PAE Read Pulse after EF HIGH 37 Min. 0.6 10 4.5 4.5 0.5 2 -- -- -- 8 Max. 8 -- -- -- -- -- 8 8 8 -- 7-5ns Min. Max. 0.6 10 12 -- 5 -- 5 -- 0.5 -- 2.5 -- -- 10 -- 10 -- 10 10 -- Unit ns ns ns ns ns ns ns ns ns ns IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES SCLK tSENS tSENH tENH SWEN tDS tDH BIT X EMPTY OFFSET BIT 0 FULL OFFSET BIT X 6357 drw43 SI BIT 0 NOTES: 1. Settings: JSEL = LOW. 2. x is the required number of bits to program the PAE and PAF offset registers. See Table 5 for the numbers based on the values external configurations. Figure 29. Serial Loading of Programmable Flag Registers (IDT Standard and FWFT Modes) tSCKH tSCLK tSCKL SCLK tSENS tSENH SREN tASO SDO BIT 0 (LSB) EMPTY OFFSET BIT X BIT 0 FULL OFFSET BIT X (MSB) 6357 drw44 NOTES: 1. Settings: JSEL = LOW. 2. x is the required number of bits to program the PAE and PAF offset registers. See Table 5 for the numbers based on the values external configurations. Figure 30. Reading of Programmable Flag Registers (IDT Standard and FWFT Modes) 6ns Symbol tDH tDS tASO tSENS tSENH tSCLK tSCLKH tSCLKL Parameter Data Hold Time Data Setup Time Serial Output Data Access Time Serial Enable Setup Serial Enable Hold Serial Clock Cycle Serial Clock HIGH Serial Clock LOW Min. 0.5 2 -- 5 5 10 45 45 Max. -- -- 20 -- -- -- -- -- 7-5ns Min. Max. 0.5 -- 2.5 -- -- 20 5 -- 5 -- 10 -- 45 -- 45 -- Unit ns ns ns ns ns ns ns ns 38 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES tTCK t4 t1 TCK t2 t3 TDI/ TMS tDS TDO tDH TDO tDO Notes to diagram: t1 = tTCKLOW t2 = tTCKHIGH t3 = tTCKFALL t4 = tTCKRISE 6357 drw45 Figure 31. Standard JTAG Timing JTAG AC ELECTRICAL CHARACTERISTICS SYSTEM INTERFACE PARAMETERS IDT72T6360 JTAG Clock Input Period tTCK Parameter Data Output Data Output Hold Data Input Symbol tDO(1) tDOH(1) tDS tDH trise=3ns tfall=3ns Test Conditions Min. 0 10 10 (vcc = 2.5V 5%; Tambient (Industrial) = 0C to +85C) Parameter Symbol Test Conditions Min. 100 40 40 Max. Units 5 (1) ns ns ns ns ns Max. Units 20 - JTAG Clock HIGH JTAG Clock Low JTAG Clock Rise Time JTAG Clock Fall Time NOTE: 1. Guaranteed by design. tTCKHIGH tTCKLOW tTCKRISE tTCKFALL ns ns ns 5(1) NOTE: 1. 50pf loading on external output signals. 39 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES JTAG TIMING SPECIFICATIONS (IEEE 1149.1 COMPLIANT) The JTAG test port in this device is fully compliant with the IEEE Standard Test Access Port (IEEE 1149.1) specifications. Four additional pins (TDI, TDO, TMS and TCK) are provided to support the JTAG boundary scan interface. Note that IDT provides appropriate Boundary Scan Description Language program files for these devices. * * * * * * The Standard JTAG interface consists of seven basic elements: Test Access Port (TAP) TAP controller Instruction Register (IR) Data Register Port (DR) Bypass Register (BYR) ID Code Register The following sections provide a brief description of each element. For a complete description refer to the IEEE Standard Test Access Port Specification (IEEE Std. 1149.1-1990). The Figure below shows the standard Boundary-Scan Architecture All inputs Eg: Dins, Clks (BSDL file describes the chain order) In Pad Incell Core Logic Outcell Out Pad All outputs In Pad Incell Outcell Out Pad TDI ID Bypass TMS TCK Instruction Register TAP Instruction Select Enable 6357 drw46 TDO Figure 32. JTAG Architecture TEST ACCESS PORT (TAP) The TAP interface is a general-purpose port that provides access to the internal JTAG state machine. It consists of three input ports (TCLK, TMS, TDI) and one output port (TDO). THE TAP CONTROLLER The TAP controller is a synchronous finite state machine that responds to TMS and TCLK signals to generate clock and control signals to the Instruction and Data Registers for capture and updating of data passed through the TDI serial input. 40 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES 1 Test-Logic Reset 0 1 1 1 SelectIR-Scan 1 0 Capture-IR 0 Shift-IR 1 1 Exit1-IR 0 Pause-IR 1 0 Exit2-IR 1 Update-IR 1 0 6357 drw47 Input is TMS 0 Run-Test/ Idle SelectDR-Scan 0 1 Capture-DR 00 Shift-DR 1 Exit1-DR 00 Pause-DR 1 0 Exit2-DR 1 Update-DR 1 0 0 1 0 NOTES: 1. Five consecutive 1's at TMS will reset the TAP. 2. TAP controller resets automatically upon power-up. Figure 33. TAP Controller State Diagram Refer to the IEEE Standard Test Access Port Specification (IEEE Std. 1149.1) for the full state diagram All state transitions within the TAP controller occur at the rising edge of the TCLK pulse. The TMS signal level (0 or 1) determines the state progression that occurs on each TCLK rising edge. Test-Logic-Reset All test logic is disabled in this controller state enabling the normal operation of the IC. The TAP controller state machine is designed in such a way that, no matter what the initial state of the controller is, the Test-Logic-Reset state can be entered by holding TMS at high and pulsing TCK five times. Run-Test-Idle In this controller state, the test logic in the IC is active only if certain instructions are present. For example, if an instruction activates the self test, then it will be executed when the controller enters this state. The test logic in the IC is idle otherwise. Select-DR-Scan This is a controller state where the decision to enter the Data Path or the Select-IR-Scan state is made. Select-IR-Scan This is a controller state where the decision to enter the Instruction Path is made. The Controller can return to the Test-Logic-Reset state other wise. Capture-IR In this controller state, the shift register bank in the Instruction Register parallel loads a pattern of fixed values on the rising edge of TCK. The last two significant bits are always required to be "01". 41 Shift-IR In this controller state, the instruction register gets connected between TDI and TDO, and the captured pattern gets shifted on each rising edge of TCK. The instruction available on the TDI pin is also shifted in to the instruction register. TDO changes on the falling edge of TCK. Exit1-IR This is a controller state where a decision to enter either the PauseIR state or Update-IR state is made. Pause-IR This state is provided in order to allow the shifting of instruction register to be temporarily halted. Exit2-DR This is a controller state where a decision to enter either the ShiftIR state or Update-IR state is made. Update-IR In this controller state, the instruction in the instruction register scan chain is latched in to the register of the Instruction Register on every falling edge of TCK. This instruction also becomes the current instruction once it is latched. Capture-DR In this controller state, the data is parallel loaded in to the data registers selected by the current instruction on the rising edge of TCK. Shift-DR, Exit1-DR, Pause-DR, Exit2-DR and Update-DR These controller states are similar to the Shift-IR, Exit1-IR, Pause-IR, Exit2-IR and Update-IR states in the Instruction path. IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES THE INSTRUCTION REGISTER The instruction register (IR) is eight bits long and tells the device what instruction is to be executed. Information contained in the instruction includes the mode of operation (either normal mode, in which the device performs its normal logic function, or test mode, in which the normal logic function is inhibited or altered), the test operation to be performed, which of the four data registers is to be selected for inclusion in the scan path during data-register scans, and the source of data to be captured into the selected data register during Capture-DR. TEST DATA REGISTER The Test Data register contains three test data registers: the Bypass, the Boundary Scan register and Device ID register. These registers are connected in parallel between a common serial input and a common serial data output. The following sections provide a brief description of each element. For a complete description, refer to the IEEE Standard Test Access Port Specification (IEEE Std. 1149.1-1990). TEST BYPASS REGISTER The register is used to allow test data to flow through the device from TDI to TDO. It contains a single stage shift register for a minimum length in the serial path. When the bypass register is selected by an instruction, the shift register stage is set to a logic zero on the rising edge of TCLK when the TAP controller is in the Capture-DR state. The operation of the bypass register should not have any effect on the operation of the device in response to the BYPASS instruction. THE BOUNDARY-SCAN REGISTER The boundary-scan register (BSR) contains one boundary-scan cell (BSC) for each normal-function input pin and one BSC for each normal-function I/O pin (one single cell for both input data and output data). The BSR is used 1) to store test data that is to be applied externally to the device output pins, and/ or 2) to capture data that appears internally at the outputs of the normal on-chip logic and/or externally at the device input pins. THE DEVICE IDENTIFICATION REGISTER The Device Identification Register is a Read Only 32-bit register used to specify the manufacturer, part number and version of the device to be determined through the TAP in response to the IDCODE instruction. IDT JEDEC ID number is 0xB3. This translates to 0x33 when the parity is dropped in the 11-bit Manufacturer ID field. For the IDT72T6360, the Part Number field contains the following values: JTAG INSTRUCTION REGISTER The Instruction register allows an instruction to be serially input into the device when the TAP controller is in the Shift-IR state. The instruction is decoded to perform the following: * Select test data registers that may operate while the instruction is current. The other test data registers should not interfere with chip operation and the selected data register. * Define the serial test data register path that is used to shift data between TDI and TDO during data register scanning. The Instruction Register is a 4 bit field (i.e. IR3, IR2, IR1, IR0) to decode 16 different possible instructions. Instructions are decoded as follows. Hex Value 0000 0001 0002 0003 0004 000F Instruction EXTEST SAMPLE/PRELOAD IDCODE CLAMP HIGH-IMPEDANCE BYPASS Private Function Test external pins Select boundary scan register Selects chip identification register Fix the output chains to scan chain values Puts all outputs in high-impedance state Select bypass register Several combinations are private (for IDT internal use). Do not use codes other than those identified above. JTAG INSTRUCTION REGISTER DECODING The following sections provide a brief description of each instruction. For a complete description refer to the IEEE Standard Test Access Port Specification (IEEE Std. 1149.1-1990). EXTEST The required EXTEST instruction places the device into an external boundary-test mode and selects the boundary-scan register to be connected between TDI and TDO. During this instruction, the boundary-scan register is accessed to drive test data off-chip via the boundary outputs and receive test data off-chip via the boundary inputs. As such, the EXTEST instruction is the workhorse of IEEE. Std 1149.1, providing for probe-less testing of solder-joint opens/shorts and of logic cluster function. SAMPLE/PRELOAD The required SAMPLE/PRELOAD instruction allows the device to remain in a normal functional mode and selects the boundary-scan register to be connected between TDI and TDO. During this instruction, the boundary-scan register can be accessed via a data scan operation, to take a sample of the functional data entering and leaving the device. This instruction is also used to preload test data into the boundary-scan register before loading an EXTEST instruction. IDCODE The optional IDCODE instruction allows the device to remain in its functional mode and selects the optional device identification register to be connected between TDI and TDO. The device identification register is a 32-bit shift register 31(MSB) 28 27 12 11 1 0(LSB) containing information regarding the device manufacturer, device type, and version code. Accessing the device identification register does not interfere with Version (4 bits) Part Number (16-bit) Manufacturer ID (11-bit) the operation of the device. Also, access to the device identification register 0000 0033 (hex) 1 should be immediately available, via a TAP data-scan operation, after powerIDT72T6360 JTAG Device Identification Register up of the device or by otherwise moving to the Test-Logic-Reset state. Device IDT72T6360 Part# Field 0437 (hex) 42 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES CLAMP The optional CLAMP instruction sets the outputs of an device to logic levels determined by the contents of the boundary-scan register and selects the onebit bypass register to be connected between TDI and TDO. Before loading this instruction, the contents of the boundary-scan register can be preset with the SAMPLE/PRELOAD instruction. During this instruction, data can be shifted through the bypass register from TDI to TDO without affecting the condition of the outputs. HIGH-IMPEDANCE The optional High-Impedance instruction sets all outputs (including two-state as well as three-state types) of an device to a disabled (high-impedance) state and selects the one-bit bypass register to be connected between TDI and TDO. During this instruction, data can be shifted through the bypass register from TDI to TDO without affecting the condition of the device outputs. BYPASS The required BYPASS instruction allows the device to remain in a normal functional mode and selects the one-bit bypass register to be connected between TDI and TDO. The BYPASS instruction allows serial data to be transferred through the IC from TDI to TDO without affecting the operation of the device. 43 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES DEPTH EXPANSION CONFIGURATION The sequential flow-control (SFC) device can be connected with multiple SFCs in depth expansion to provide additional storage density that's greater than 1Gb. In depth expansion mode, two or mode devices are connected through a common transfer interface, as shown in Figure 34. The transfer clock can be a separate free-running clock or driven from the same system write or read clock. In depth expansion configuration, the first word written to an empty configuration will pass from the first SFC to the next until it appears on the second (or last) SFC in the chain. If no reads are performed, data will begin accumulating in the second SFC until it is full. Once the second SFC is full it will disable the REN to the first SFC. At this point data will begin accumulating in the first SFC. Once both devices are full, the entire configuration is full and the full flag indicator will go LOW. For an empty configuration, the amount of time it takes for the empty flag of the second (or last) SFC in the chain to go LOW (i.e. valid data available to be read out of the device) after a word has been written into the first FIFO is the sum of the delays for each individual SFC: (N - 1) x (4 x transfer clock) + 3 x RCLK Where N is the number of SFCs in the chain and RCLK is the RCLK period in ns. This latency is only noticeable for the first word written to an empty configuration. There will be no delay evident for subsequent words written into the chain. In the full configuration, the amount of time it takes for the FF of the first SFC to go from LOW to HIGH after reading one word from the chain is the sum of the delays for each individual SFC: (N - 1) x (3 x transfer clock) + 2 x WCLK Depth expansion is available in both IDT Standard mode and First Word Fall Through (FWFT) mode. If IDT Standard mode is selected, the IDEM signal needs to be HIGH. If FWFT mode is selected, the IDEM signal needs to be LOW. VCC GND Transfer Clock Write Clock Write Enable Full Flag Data Inputs Dn IDEM Qn Dn IDEM Qn FWFT WCLK WEN FF SFC #1 RCLK EF REN WCLK WEN FF SFC #2 FWFT RCLK Read Clock EF REN Empty Flag Read Enable Data Outputs 6357 drw48 VCC VCC Figure 34. Depth Expansion Configuration in IDT Standard Mode VCC Transfer Clock Write Clock Write Enable Input Ready Flag Data Inputs Dn IDEM Qn Dn IDEM Qn FWFT WCLK WEN IR SFC #1 RCLK OR REN WCLK WEN IR SFC #2 FWFT RCLK Read Clock OR REN Output Ready Flag Read Enable Data Outputs 6357 drw49 GND GND Figure 35. Depth Expansion Configuration in FWFT Mode 44 IDT72T6360 2.5V, SEQUENTIAL FLOW-CONTROL DEVICE x9, x18, x36 BIT WIDE CONFIGURATION COMMERCIAL AND INDUSTRIAL TEMPERATURE RANGES WIDTH EXPANSION CONFIGURATION The sequential flow-control (SFC) device can be connected with another SFCs in width expansion to support bus-widths greater than 36-bits. This configuration connects the input and output bus of two devices together to create a wider bus. The read and write clocks for each device are driven with a clock driver. The empty and full flags of both devices are connected to a logic gate (AND/OR) depending on whether IDT Standard mode or FWFT mode is selected. Because of the variation in skew between the read clock and write clock, it is possible for EF/FF deassertion and IR/OR assertion to vary from one cycle between the devices. The logic gate connected to the status flags will create a composite flag that will update the status of both SFC devices to represent a more accurate status of the configuration. To minimize the skew between the two write and read clocks, a clock driver (IDT5T905 recommended) is used to drive the input clocks for both SFC devices. Figure 36 illustrates the width expansion configuration. Clock Driver IDT5T905 Write Clock Write Enable Full Flag/Input Ready Data Inputs SFC WCLK WEN FF/IR Dn RCLK REN EF/OR Read Clock Read Enable Empty Flag/Output Ready Data Outputs Clock Driver IDT5T905 Gate (1) 64 36 Qn 36 64 Gate (1) Clock Driver IDT5T905 Write Clock WCLK WEN Full Flag/Input Ready 36 FF/IR Dn SFC RCLK REN EF/OR Qn 36 Read Clock Clock Driver IDT5T905 Empty Flag/Output Ready 6357 drw50 NOTES: 1. Use an AND gate in IDT Standard mode, an OR gate in FWFT mode. 2. Do not connect any output signals directly together. Figure 36. Width Expansion Configuration in IDT Standard Mode and FWFT Mode 45 ORDERING INFORMATION IDT XXXXX Device Type X Power XX Speed X Package X Process / Temperature Range BLANK I(1) BB Commercial (0C to +70C) Industrial (-40C to +85C) Plastic Ball Grid Array (PBGA, BB324) 6 7.5 L 72T6360 Commercial Only Commercial and Industrial Low Power Clock Cycle Time (tCLK) Speed in Nanoseconds 2.5V Sequential Flow Control Device configurable to x9, x18, or x36 6357 drwlast CORPORATE HEADQUARTERS 2975 Stender Way Santa Clara, CA 95054 for SALES: 800-345-7015 or 408-727-6116 fax: 408-492-8674 www.idt.com 46 for Tech Support: 408-330-1533 email: Flow-Controlhelp@idt.com |
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