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ds07-12605-1e fujitsu semiconductor data sheet copyright?2006 fujitsu li mited all rights reserved ?check sheet? is seen at the following support page url : http://www.fujitsu.com/global/services/micr oelectronics/product/micom/support/index.html ?check sheet? lists the minimal require ment items to be checked to prevent problems beforehand in system development. be sure to refer to the ?check sheet? for the latest cautions on development. 8-bit proprietary microcontrollers cmos f 2 mc-8fx mb95110h series mb95117h/f118hs/f118ts/f118hw/f118tw/ mb95fv100b-103 description the mb95110h series is general-purpose, single-chip micr ocontrollers. in addition to a compact instruction set, the microcontrollers contain a variety of peripheral functions. note : f 2 mc is the abbreviation of fujitsu flexible microcontroller. features ? f 2 mc-8fx cpu core instruction set optimized for controllers multiplication and division instructions 16-bit arithmetic operations bit test branch instruction bit manipulation instructions etc. ? clock main clock main pll clock sub clock (for dual clock product) sub pll clock (for dual clock product) ? timer 8/16-bit compound timer 2 channels 8/16-bit ppg 2 channels 16-bit ppg timebase timer watch prescaler (for dual clock product) (continued)
mb95110h series 2 (continued) ? lin-uart full duplex double buffer clock asynchronous or clock synchronous serial data transfer capable ? uart/sio full duplex double buffer clock asynchronous or clock synchronous serial data transfer capable ? i 2 c* built-in wake-up function ? external interrupt interrupt by edge detection (rising, falling, or both edges can be selected) can be used to recover from lo w-power consumption (standby) modes. ? 8/10-bit a/d converter 8-bit or 10-bit resolution can be selected ? low-power consumption (standby) mode stop mode sleep mode watch mode (for dual clock product) timebase timer mode ? i/o port the number of maximum ports ? single clock product : 39 ports ? dual clock product : 37 ports configuration ? general-purpose i/o ports (n-ch open drain) : 2 ports ? general-purpose i/o ports (cmos) : single clock product : 37 ports dual clock product : 35 ports * : purchase of fujitsu i 2 c components conveys a license under the philips i 2 c patent rights to use, these com- ponents in an i 2 c system provided that the system conforms to the i 2 c standard specificat ion as defined by philips.
mb95110h series 3 product lineup (continued) part number parameter mb95117h mb95f118hs mb95f118 ts mb95f118hw mb95f118tw type mask rom product flash memory product rom capacity 48 kbytes 60 kbytes ram capacity 2 kbytes 2 kbytes reset output yes clock system selectable single/dual clock* 1 single clock dual clock low voltage detection reset yes / no no yes no yes cpu functions number of basic instructions : 136 instruction bit length : 8 bits instruction length : 1 to 3 bytes data bit length : 1, 8, and 16 bits minimum instruction execution time : 0.1 s (at machine clock frequency 10 mhz) interrupt processing time : 0.9 s (at machine clock frequency 10 mhz) general purpose i/o ports ? single clock product : 39 ports (n-c h open drain : 2 ports, cmos : 37 ports) ? dual clock product : 37 ports (n-c h open drain : 2 ports, cmos : 35 ports) timebase timer interrupt cycle : 0.5 ms, 2.1 ms, 8. 2 ms, 32.8 ms (at main oscillation clock 4 mhz) watchdog timer reset generated cycle at main oscillation clock 10 mhz : min 105 ms at sub oscillation clock 32.768 khz (for dual clock product) : min 250 ms wild register capable of replacing 3 bytes of rom data i 2 c master/slave sending and receiving bus error function an d arbitration function detecting transmitting direction function start condition repeated generat ion and detection functions built-in wake-up function uart/sio data transfer capable in uart/sio full duplex double buffer, variable data length (5/6/7/8-bit), built-in baud rate generator transfer rate : 2400 bps to 12500 00 bps (at machine clock 10 mhz) nrz type transfer format, error detected function lsb-first or msb-first can be selected. clock synchronous (sio) or clock asynchr onous (uart) serial data transfer capable option* 2 peripheral functions
mb95110h series 4 (continued) the evaluation device of this product is mb95fv100b-103. mcu board is mb2146-303. *1 : specify clock mode when ordering mask rom. *2 : for details of option, refer to ? mask option?. note : part number of the evaluation device in mb95 110h series is mb95fv100b-1 03. when using it, the mcu board (mb2146-303) is required. part number parameter mb95117h mb95f118hs mb95f118 ts mb95f118hw mb95f118tw lin-uart dedicated reload timer allowing a wide range of communication speeds to be set. full duplex double buffer. capable of serial data transfer synchr onous or asynchronous to clock signal. lin functions available as the lin master or lin slave. 8/10-bit a/d converter (8 channels) 8-bit or 10-bit resolution can be selected. 8/16-bit compound timer (2 channels) each channel of the timer c an be used as ?8-bit timer 2 channels? or ?16-bit timer 1 channel?. built-in timer function, pwc function, pw m function, capture function, and square waveform output count clock : 7 internal clocks and external clock can be selected 16-bit ppg pwm mode or one-shot mode can be selected. counter operating clock : 8 selectable clock sources support for external trigger start 8/16-bit ppg (2 channels) each channel of the ppg can be used as ? 8-bit ppg 2 channels ? or ? 16-bit ppg 1 channel ? . counter operating clock : eight selectable clock sources watch counter (for dual clock product) count clock : 4 selectable clock sour ces (125 ms, 250 ms, 500 ms, or 1 s) counter value can be set from 0 to 63. (capable of counting for 1minute when selecting clock source 1 second and setting counter value to 60) watch prescaler (for dual clock product) 4 selectable interval times (125 ms, 250 ms, 500 ms, or 1 s) external interrupt (12 channels) interrupt by edge detection (rising, fa lling, or both edges can be selected.) can be used to recove r from standby modes. standby mode sleep, stop, watch (for du al clock product) , and timebase timer peripheral functions
mb95110h series 5 oscillation stabilization wait time the initial value of the main clock oscillation stabilization wait time is fixed to the maximum value. the maximum value is shown as follows. packages and corresponding products : available : unavailable oscillation stabilization wait time remarks (2 14 ? 2) /f ch approx. 4.10 ms (at main oscillation clock 4 mhz) part number package mb95117h mb95f118hs mb95f118ts mb95f118hw mb95f118tw mb95fv100b-103 fpt-52p-m01 bga-224p-m08
mb95110h series 6 differences among products and notes on selecting products ? notes on using evaluation products the evaluation product has not only t he functions of the mb95110h series but also those of other products to support software development for mult iple series and models of the f 2 mc-8fx family. the i/o addresses for peripheral resources not used by the mb95110h series are therefore access-b arred. read/write access to these access-barred addresses may cause peripheral resour ces supposed to be unused to operate, resulting in unexpected malfunctions of hardware or software. particularly, do not use word access to odd numbered by te address in the prohibited areas (if these access are used, the address may be read or write unexpectedly) . note that the values read from barred addresses are different between the evaluation product and the flash memory or mask rom product. therefore, th e data must not be used for software processing. the evaluation product do not support the functions of some bits in single-byte registers. read/write access to these bits does not cause hardware malfunctions. sinc e the evaluation, flash memory, and mask rom products are designed to behave completely the same way in terms of hardware and software. ? difference of memory spaces if the amount of memory on the evaluation product is di fferent from that of the flash memory or mask rom product, carefully check the differ ence in the amount of memory from the model to be actually used when developing software. for details of memory space, refer to ? cpu core?. ? current consumption the current consumption of flash memory produc t is typically greater t han for mask rom product. for details of current consumption, refer to ? electrical characteristics?. ? package for details of information on each package, refer to ? package and corresponding products? and ? package dimensions?. ? operating voltage the operating voltage are different among the ev aluation, flash memory, and mask rom products. for details of operating voltage, refer to ? electrical characteristics? ? difference between rst and mod pins the input type of rst and mod pins is cmos input s on the flash memory product. the rst and mod pins are hysteresis inputs on the mask ro m product. a pull-down resistor is provided for the mod pin of the mask rom product.
mb95110h series 7 pin assignments 1 2 3 4 5 6 7 8 9 10 11 12 13 p65/sck p66/sot p67/sin p37/an07 p36/an06 p35/an05 nc p34/an04 p33/an03 p32/an02 p31/an01 p30/an00 avss p06/int06 p05/int05 p04/int04 p03/int03 p02/int02 p01/int01 nc p00/int00 rst pg1/x0a* pg2/x1a* c vcc 14 15 16 17 18 19 20 21 22 23 26 avcc vss x1 x0 mod p50/scl0 p51/sda0 p20/ppg00 p21/ppg01 p22/to00 p23/to01 p24/ec0 24 25 39 38 37 36 35 34 33 32 31 30 29 28 27 52 51 50 49 48 47 46 45 44 43 40 42 41 nc p10/ui0 p07/int07 p11/uo0 p12/uck0 p13/trg0/adtg p14/ppg0 p15 p60/ppg10 p61/ppg11 p62/to10 p63/to11 p64/ec1 nc (fpt-52p-m01) (top view) * : single clock product is general-purpose port, and dual clock product is sub clock oscillation pin.
mb95110h series 8 pin description (continued) pin no. pin name i/o circuit type* function 1 p65/sck k general-purpose i/o port. the pin is shared with lin-uart clock i/o. 2 p66/sot general-purpose i/o port. the pin is shared with lin-uart data output. 3 p67/sin l general-purpose i/o port. the pin is shared with lin-uart data input. 4 p37/an07 j general-purpose i/o port. the pins are shared with a/d converter analog input. 5 p36/an06 6 p35/an05 8 p34/an04 9 p33/an03 10 p32/an02 11 p31/an01 12 p30/an00 13 avss ? a/d converter power supply pin (gnd) 14 avcc ? a/d converter power supply pin 15 p24/ec0 h general-purpose i/o port. the pin is shared with 8/16-bit compound timer ch.0 clock input. 16 p23/to01 general-purpose i/o port. the pins are shared with 8/16-bit compound timer ch.0 output. 17 p22/to00 18 p21/ppg01 general-purpose i/o port. the pins are shared with 8/16-bit ppg ch.0 output. 19 p20/ppg00 21 p51/sda0 i general-purpose i/o port. the pin is shared with i 2 c ch.0 data i/o. 22 p50/scl0 general-purpose i/o port. the pin is shared with i 2 c ch.0 clock i/o. 23 mod b operating mode designation pin 24 x0 a main clock oscillation input pin 25 x1 main clock oscillation i/o pin 26 vss ? power supply pin (gnd) 27 vcc ? power supply pin 28 c ? capacitor connection pin 29 pg2/x1a h/a single clock product is general-purpose port (pg2). dual clock product is sub clock i/o oscillation pin (32 khz). 30 pg1/x0a single clock product is general-purpose port (pg1). dual clock product is sub clock input oscillation pin (32 khz). 31 rst b? reset pin
mb95110h series 9 (continued) *: for the i/o circuit type, refer to ? i/o circuit type? pin no. pin name i/o circuit type* function 32 p00/int00 c general-purpose i/o port. the pins are shared with external interrupt input. large current port. 34 p01/int01 35 p02/int02 36 p03/int03 37 p04/int04 38 p05/int05 39 p06/int06 40 p07/int07 41 p10/ui0 g general-purpose i/o port. the pin is shared with uart/sio ch.0 data input. 42 p11/uo0 h general-purpose i/o port. the pin is shared with uart/sio ch.0 data output. 43 p12/uck0 general-purpose i/o port. the pin is shared with uart/sio ch.0 clock i/o. 44 p13/trg0/ adtg general-purpose i/o port. the pin is shared with 16-bit pp g ch.0 trigger input (trg0) and a/d trigger input (adtg). 45 p14/ppg0 general-purpose i/o port. the pin is shared with 16-bit ppg ch.0 output. 47 p15 general-purpose i / o port. 48 p60/ppg10 k general-purpose i/o port. the pins are shared with 8/16-bit ppg ch.1 output. 49 p61/ppg11 50 p62/to10 general-purpose i/o port. the pins are shared with 8/16-bit compound timer ch.1 output. 51 p63/to11 52 p64/ec1 general-purpose i/o port. the pin is shared with 8/16-bit compound timer ch.1 clock input. 7, 20, 33, 46 nc ? internal connect pin. be sure this pin is left open.
mb95110h series 10 i/o circuit type (continued) type circuit remarks a oscillation circuit high-speed side feedback resistance : approx. 1 m ? low-speed side feedback resistance : approx. 24 m ? (evaluation product : approx. 10 m ? ) dumping resistance : approx. 144 m ? ) (evaluation product : without dumping resistance) b only for input hysteresis input only for mask rom product with pull-down resistor only for mask rom product b? hysteresis input only for mask rom product c cmos output hysteresis input g cmos output cmos input hysteresis input with pull-up control h cmos output hysteresis input with pull-up control x 0 (x0a) x1 (x1a) n-ch standby control clock inpu t mode input reset input p-ch n-ch standby control external interrupt enable digital output digital output hysteresis inpu t r p-ch n-ch p-ch pull-up control standby control digital output digital output hysteresis inpu t cmos input p-ch n-ch r p-ch pull-up control standby control digital output digital output hysteresis inp ut
mb95110h series 11 (continued) type circuit remarks i n-ch open drain output cmos input hysteresis input j cmos output hysteresis input analog input with pull-up control k cmos output hysteresis input l cmos output cmos input hysteresis input n-ch standby control digital output cmos input hysteresis inpu t r p-ch n-ch p-ch pull-up control a/d control standby control analog input digital output hysteresis input digital output p-ch n-ch standby control hysteresis inp ut digital output digital output p-ch n-ch standby control digital output hysteresis inpu t cmos input digital output
mb95110h series 12 handling devices ? preventing latch-up care must be taken to ensure that maximum vo ltage ratings are not ex ceeded when they are used. latch-up may occur on cmos ics if voltage higher than v cc or lower than v ss is applied to input and output pins other than medium- and high-withstand voltage pins or if higher than the rating voltage is applied between v cc pin and v ss pin. when latch-up occurs, power supply current incr eases rapidly and might thermally damage elements. also, take care to prevent the analog power supply voltage (av cc ) and analog input voltage from exceeding the digital power supply voltage (v cc ) when the analog system power supply is turned on or off. ? stable supply voltage supply voltage should be stabilized. a sudden change in power-supply voltage may cause a ma lfunction even within the guaranteed operating range of the vcc power-supply voltage. for stabilization, in principle, keep the variation in vcc ripple (p-p value) in a commercial frequency range (50/60 hz) not to exceed 10% of the standard vcc value an d suppress the voltage variation so that the transient variation rate does not exceed 0.1 v/ms during a mom entary change such as when the power supply is switched. ? precautions for use of external clock even when an external clock is used, oscillation stabilizat ion wait time is required for power-on reset, wake-up from sub clock mode or stop mode. pin connection ? treatment of unused pin leaving unused input pins unconnected can cause abnormal operation or latc h-up, leaving to permanent damage. unused input pins should always be pulled up or down through resistance of at least 2 k ? . any unused input/ output pins may be set to output mo de and left open, or set to input m ode and treated the same as unused input pins. if there is unused output pin, make it open. ? treatment of power supply pins on a/d converter connect to be av cc = v cc and av ss = v ss even if the a/d converter is not in use. noise riding on the av cc pin may cause accuracy degradation. so, connect approx. 0.1 f ceramic capacitor as a bypass capacitor between av cc and av ss pins in the vicinity of this device. ? power supply pins in products with multiple v cc or v ss pins, the pins of the same potentia l are internally connected in the device to avoid abnormal operations including latch-up. however, you must connect the pins to external power supply and a ground line to lower the electro- magnetic emission level, to prevent abnormal operation of strobe signals caused by the rise in the ground level, and to conform to the total output current rating. moreover, connect the current supply source with the v cc and v ss pins of this device at the low impedance. it is also advisable to connect a cerami c bypass capacitor of approximately 0.1 f between v cc and v ss pins near this device.
mb95110h series 13 ? mode pin (mod) connect the mode pin directly to v cc or v ss pins. to prevent the device unintentionally entering test mode du e to noise, lay out the printed circuit board so as to minimize the distance from the mode pins to v cc or v ss pins and to provide a low-impedance connection. use a ceramic capacitor or a capacitor with equivalent frequency characteristics. a bypass capacitor of v cc pin must have a capacitance value higher than c s . for connection of smoothing capacitor c s , see the diagram below. ? nc pins any pins marked ?nc? (not connected) must be left open. ? analog power supply always set the same potential to av cc and v cc . when v cc > av cc , the current may flow through the an00 to an07 pins. c c s c pin connection diagram
mb95110h series 14 programming flash memory microcontrollers using parallel programmer ? supported parallel programmers and adapters note : for information on applicable adapter models and parallel programmers, contact the following: flash support group, inc. tel: + 81-53-428-8380 ? sector configuration the individual sectors of flash memory correspond to addresses used for cpu access and programming by the parallel programmer as follows: ? programming method 1) set the type code of the parallel programmer to ?17222?. 2) load program data to programmer addresses 71000 h to 7ffff h . 3) programmed by parallel programmer package applicable adapter model parallel programmers fpt-52p-m01 under development af9708 (ver 02.35g or more) af9709/b (ver 02.35g or more) af9723+af9834 (ver 02.08e or more) *: programmer addresses are corresponding to cpu addre sses, used when the parallel programmer program s data into flash memory. these programmer addresses are used for the paralle l programmer to program or erase data in flash memory. flash memory cpu address programmer address* sa1 (4 kbytes) 1000 h 71000 h 1fff h 71fff h sa2 (4kbytes) 2000 h 72000 h 2fff h 72fff h sa3 (4 kbytes) 3000 h 73000 h 3fff h 73fff h sa4 (16 kbytes) 4000 h 74000 h 7fff h 77fff h sa5 (16 kbytes) 8000 h 78000 h bfff h 7bfff h sa6 (4 kbytes) c000 h 7c000 h cfff h 7cfff h sa7 (4 kbytes) d000 h 7d000 h dfff h 7dfff h sa8 (4 kbytes) e000 h 7e000 h efff h 7efff h sa9 (4 kbytes) f000 h 7f000 h ffff h 7ffff h lower bank upper bank
mb95110h series 15 block diagram p15 p65/sck p67/sin av cc av ss p50/scl0 p51/sda0 p30/an00 to p37/an07 p12/uck0 p62/to10 p61/ppg1 1 p60/ppg1 0 p63/to11 p 00/int00 to p07/int07 p10/ui0 p64/ec1 p66/sot rst x0,x1 p14/ppg0 p13/trg0/adtg p20/ppg00 p21/ppg01 p22/to00 p23/to01 p24/ec0 p11/uo0 uart/sio 16-bit ppg 8/16-bit ppg ch.0 8/10-bit a/d converter i 2 c 8/16-bit ppg ch.1 rom ram f 2 mc-8fx cpu port port 8/16-bit compound timer ch.0 8/16-bit compound timer ch.1 interrupt control wild register reset control clock control watch prescaler watch counter external interrupt internal bus pg2/x1a* pg1/x0a* lin-uart mod, v cc , v ss , c, nc * : single clock product is a general-purpose port, and dual clock product is a sub clock oscillation pin. other pins
mb95110h series 16 cpu core 1. memory space memory space of the mb95110h series is 64 kbytes an d consists of i/o area, data area, and program area. the memory space includes special-purpose areas su ch as the general-purpose registers and vector table. memory map of the mb95110h series is shown below. memory map 0000 h 0080 h 0100 h 0200 h 0f80 h 1000 h ffff h flash 60 kbytes ram 3.75 kbytes mb95fv100b-103 i/o 0000 h 0080 h 0100 h 0200 h 0880 h 0f80 h 1000 h ffff h flash 60 kbytes mb95f118hs mb95f118ts mb95f118hw mb95f118tw i/o ram 2 kbytes 0000 h 0080 h 0100 h 0200 h 0880 h 0f80 h 1000 h 4000 h ffff h rom 48 kbytes mb95117h i/o ram 2 kbytes expanded i/o register register access prohibited access prohibited access prohibited register expanded i/o expanded i/o
mb95110h series 17 2. register the mb95110h series has two types of registers; dedicated registers in t he cpu and general-purpose registers in the memory. the dedicated registers are as follows: the ps can further be divided into higher 8 bits for use as a register bank pointer (rp) and a direct bank pointer (dp) and the lower 8 bits for use as a conditi on code register (ccr) . (see the diagram below.) program counter (pc) : a 16-bit register to indi cate locations where instructions are stored. accumulator (a) : a 16-bit register for temporary st orage of arithmetic oper ations. in the case of an 8-bit data processing instruction, the lower 1 byte is used. temporary accumulator (t) : a 16-bit register which pe rforms arithmetic operations with the accumulator. in the case of an 8-bit data processing instruction, the lower 1 byte is used. index register (ix) : a 16-bit re gister for index modification. extra pointer (ep) : a 16-bit pointer to point to a memory address. stack pointer (sp) : a 16-bit register to indicate a stack area. program status (ps) : a 16-bit register for storing a register bank pointer, a direct bank pointer, and a condition code register. pc a t ix ep sp ps : program counter 16-bit : accumulator : temporary accumulator : index register : extra pointer : stack pointer : program status initial value fffd h 0000 h 0000 h 0000 h 0000 h 0000 h 0030 h p s rp ccr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 dp2 dp1 dp0 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 r4 r3 r2 r1 r0 h i il1 il0 n z v c dp ? structure of the program status
mb95110h series 18 the rp indicates the address of th e register bank currently being used . the relationship between the content of rp and the real address conforms to the conversion rule illustrated below: the dp specifies the area for mapping instructions (16 di fferent instructions such as mov a, dir) using direct addresses to 0080 h to 00ff h . the ccr consists of the bits indicating arithmetic opera tion results or transfer data contents and the bits that control cpu operations at interrupt. direct bank pointer (dp2 to dp0) specified address area mapping area xxx b (no effect to mapping) 0000 h to 007f h 0000 h to 007f h (without mapping) 000 b (initial value) 0080 h to 00ff h 0080 h to 00ff h (without mapping) 001 b 0100 h to 017f h 010 b 0180 h to 01ff h 011 b 0200 h to 027f h 100 b 0280 h to 02ff h 101 b 0300 h to 037f h 110 b 0380 h to 03ff h 111 b 0400 h to 047f h h flag : set to ?1? when a carry or a borrow from bit 3 to bit 4 occurs as a result of an arithmetic operation. cleared to ?0? otherwise. this flag is for decimal adjustment instructions. i flag : interrupt is enabled when this flag is set to ?1 ?. interrupt is disabled when this flag is set to ?0?. the flag is set to ?0? when reset. il1, il0 : indicates the level of the interrupt currently enabled. processes an interrupt only if its request level is higher than the value indicated by these bits. il1 il0 interrupt level priority 00 0 high low = no interruption 01 1 10 2 11 3 n flag : set to ?1? if the msb is set to ?1? as the re sult of an arithmetic operation. cleared to ?0? when the bit is set to ?0?. z flag : set to ?1? when an arithmetic operati on results in ?0?. cleared to ?0? otherwise. v flag : set to ?1? if the complement on 2 overflows as a result of an arithmetic operation. cleared to ?0? otherwise. c flag : set to ?1? when a carry or a borrow from bit 7 oc curs as a result of an arithmetic operation. cleared to ?0? otherwise. set to the shift-out va lue in the case of a shift instruction. "0" "0" "0" "0" "0" "0" "0" "1" r4 r3 r2 r1 r0 b2 b1 b0 a7 a6 a5 a4 a3 a2 a1 a0 a15 a14 a13 a12 a11 a10 a9 a8 ? rule for conversion of actual addresse s in the general-purpose register area generated address rp upper op code lower
mb95110h series 19 the following general-purpose registers are provided: general-purpose registers: 8-bit data storage registers the general-purpose registers are 8 bits and located in the register banks on the memory. 1-bank contains 8-register. up to a total of 32 banks can be used on the mb95110h series. the bank currently in use is specified by the register bank pointer (rp), and the lower 3 bits of op code indicates the general-purpose register 0 (r0) to general-purpose register 7 (r7). r0 r1 r2 r3 r4 r5 r6 r7 r0 t his address = 0100 h + 8 (rp) r1 r2 r3 r4 r5 r6 r7 r0 r1 r2 r3 r4 r5 r6 r7 address 100 h 107 h 1f8 h 1ff h bank 31 bank 0 8-bit register bank configuration 32 banks memory area 32 banks (ram area) the number of banks is limited by the usable ram capacitance.
mb95110h series 20 i/o map (continued) address register abbreviation register name r/w initial value 0000 h pdr0 port 0 data register r/w 00000000 b 0001 h ddr0 port 0 direction register r/w 00000000 b 0002 h pdr1 port 1 data register r/w 00000000 b 0003 h ddr1 port 1 direction register r/w 00000000 b 0004 h ? (disabled) ?? 0005 h watr oscillation stabilization wait time setting register r/w 11111111 b 0006 h pllc pll control register r/w 00000000 b 0007 h sycc system clock control register r/w 1010x011 b 0008 h stbc standby control register r/w 00000000 b 0009 h rsrr reset source register r xxxxxxxx b 000a h tbtc timebase timer control register r/w 00000000 b 000b h wpcr watch prescaler cont rol register r/w 00000000 b 000c h wdtc watchdog timer control register r/w 00000000 b 000d h ? (disabled) ?? 000e h pdr2 port 2 data register r/w 00000000 b 000f h ddr2 port 2 direction register r/w 00000000 b 0010 h pdr3 port 3 data register r/w 00000000 b 0011 h ddr3 port 3 direction register r/w 00000000 b 0012 h , 0013 h ? (disabled) ?? 0014 h pdr5 port 5 data register r/w 00000000 b 0015 h ddr5 port 5 direction register r/w 00000000 b 0016 h pdr6 port 6 data register r/w 00000000 b 0017 h ddr6 port 6 direction register r/w 00000000 b 0018 h to 0029 h ? (disabled) ?? 002a h pdrg port g data register r/w 00000000 b 002b h ddrg port g direction register r/w 00000000 b 002c h ? (disabled) ?? 002d h pul1 port 1 pull-up register r/w 00000000 b 002e h pul2 port 2 pull-up register r/w 00000000 b 002f h pul3 port 3 pull-up register r/w 00000000 b 0030 h to 0034 h ? (disabled) ??
mb95110h series 21 (continued) address register abbreviation register name r/w initial value 0035 h pulg port g pull-up register r/w 00000000 b 0036 h t01cr1 8/16-bit compound timer 01 contro l status register 1 ch.0 r/w 00000000 b 0037 h t00cr1 8/16-bit compound timer 00 contro l status register 1 ch.0 r/w 00000000 b 0038 h t11cr1 8/16-bit compound timer 11 contro l status register 1 ch.1 r/w 00000000 b 0039 h t10cr1 8/16-bit compound timer 10 contro l status register 1 ch.1 r/w 00000000 b 003a h pc01 8/16-bit ppg1 contro l register ch.0 r/w 00000000 b 003b h pc00 8/16-bit ppg0 contro l register ch.0 r/w 00000000 b 003c h pc11 8/16-bit ppg1 contro l register ch.1 r/w 00000000 b 003d h pc10 8/16-bit ppg0 contro l register ch.1 r/w 00000000 b 003e h to 0041 h ? (disabled) ?? 0042 h pcnth0 16-bit ppg status control re gister (upper byte) ch.0 r/w 00000000 b 0043 h pcntl0 16-bit ppg status control re gister (lower byte) ch.0 r/w 00000000 b 0044 h to 0047 h ? (disabled) ?? 0048 h eic00 external interrupt circuit control register ch.0/1 r/w 00000000 b 0049 h eic10 external interrupt circuit control register ch.2/3 r/w 00000000 b 004a h eic20 external interrupt circuit control register ch.4/5 r/w 00000000 b 004b h eic30 external interrupt circuit control register ch.6/7 r/w 00000000 b 004c h to 004f h ? (disabled) ?? 0050 h scr lin-uart serial control register r/w 00000000 b 0051 h smr lin-uart serial mode register r/w 00000000 b 0052 h ssr lin-uart serial status register r/w 00001000 b 0053 h rdr/tdr lin-uart reception/transmission data register r/w 00000000 b 0054 h escr lin-uart extended status control register r/w 00000100 b 0055 h eccr lin-uart extended communication control register r/w 000000xx b 0056 h smc10 uart/sio serial mode control register 1 ch.0 r/w 00000000 b 0057 h smc20 uart/sio serial mode control register 2 ch.0 r/w 00100000 b 0058 h ssr0 uart/sio serial status register ch.0 r/w 00000001 b 0059 h tdr0 uart/sio serial output data register ch.0 r/w 00000000 b 005a h rdr0 uart/sio serial input data register ch.0 r 00000000 b 005b h to 005f h ? (disabled) ??
mb95110h series 22 (continued) address register abbreviation register name r/w initial value 0060 h ibcr00 i 2 c bus control register 0 ch.0 r/w 00000000 b 0061 h ibcr10 i 2 c bus control register 1 ch.0 r/w 00000000 b 0062 h ibsr0 i 2 c bus status register ch.0 r 00000000 b 0063 h iddr0 i 2 c data register ch.0 r/w 00000000 b 0064 h iaar0 i 2 c address register ch.0 r/w 00000000 b 0065 h iccr0 i 2 c clock control register ch.0 r/w 00000000 b 0066 h to 006b h ? (disabled) ?? 006c h adc1 8/10-bit a/d converter control register 1 r/w 00000000 b 006d h adc2 8/10-bit a/d converter control register 2 r/w 00000000 b 006e h addh 8/10-bit a/d converter data register (upper byte) r/w 00000000 b 006f h addl 8/10-bit a/d converter data register (lower byte) r/w 00000000 b 0070 h wcsr watch counter status register r/w 00000000 b 0071 h ? (disabled) ?? 0072 h fsr flash memory status register r/w 000x0000 b 0073 h swre0 flash memory sector writing control register 0 r/w 00000000 b 0074 h swre1 flash memory sector writing control register 1 r/w 00000000 b 0075 h ? (disabled) ?? 0076 h wren wild register address co mpare enable register r/w 00000000 b 0077 h wror wild register data test setting register r/w 00000000 b 0078 h ? (mirror of register bank pointer (rp) and direct bank pointer (dp) ) ?? 0079 h ilr0 interrupt level setting register 0 r/w 11111111 b 007a h ilr1 interrupt level setting register 1 r/w 11111111 b 007b h ilr2 interrupt level setting register 2 r/w 11111111 b 007c h ilr3 interrupt level setting register 3 r/w 11111111 b 007d h ilr4 interrupt level setting register 4 r/w 11111111 b 007e h ilr5 interrupt level setting register 5 r/w 11111111 b 007f h ? (disabled) ?? 0f80 h wrarh0 wild register address setting register (upper byte) ch.0 r/w 00000000 b 0f81 h wrarl0 wild register address setting register (lower byte) ch.0 r/w 00000000 b 0f82 h wrdr0 wild register data setting register ch.0 r/w 00000000 b 0f83 h wrarh1 wild register address setting register (upper byte) ch.1 r/w 00000000 b 0f84 h wrarl1 wild register address setting register (lower byte) ch.1 r/w 00000000 b 0f85 h wrdr1 wild register data setting register ch.1 r/w 00000000 b
mb95110h series 23 (continued) address register abbreviation register name r/w initial value 0f86 h wrarh2 wild register address setting re gister (upper byte) ch.2 r/w 00000000 b 0f87 h wrarl2 wild register address setting re gister (lower byte) ch.2 r/w 00000000 b 0f88 h wrdr2 wild register data setting register ch.2 r/w 00000000 b 0f89 h to 0f91 h ? (disabled) ?? 0f92 h t01cr0 8/16-bit compound timer 01 contro l status register 0 ch.0 r/w 00000000 b 0f93 h t00cr0 8/16-bit compound timer 00 contro l status register 0 ch.0 r/w 00000000 b 0f94 h t01dr 8/16-bit compound timer 01 data register ch.0 r/w 00000000 b 0f95 h t00dr 8/16-bit compound timer 00 data register ch.0 r/w 00000000 b 0f96 h tmcr0 8/16-bit compound timer 00/01 timer mode control register ch.0 r/w 00000000 b 0f97 h t11cr0 8/16-bit compound timer 11 contro l status register 0 ch.1 r/w 00000000 b 0f98 h t10cr0 8/16-bit compound timer 10 contro l status register 0 ch.1 r/w 00000000 b 0f99 h t11dr 8/16-bit compound timer 11 data register ch.1 r/w 00000000 b 0f9a h t10dr 8/16-bit compound timer 10 data register ch.1 r/w 00000000 b 0f9b h tmcr1 8/16-bit compound timer 10/11 timer mode control register ch.1 r/w 00000000 b 0f9c h pps01 8/16-bit ppg1 cycle setting buffer register ch.0 r/w 11111111 b 0f9d h pps00 8/16-bit ppg0 cycle setting buffer register ch.0 r/w 11111111 b 0f9e h pds01 8/16-bit ppg1 duty setting buffer register ch.0 r/w 11111111 b 0f9f h pds00 8/16-bit ppg0 duty setting buffer register ch.0 r/w 11111111 b 0fa0 h pps11 8/16-bit ppg1 cycle setting buffer register ch.1 r/w 11111111 b 0fa1 h pps10 8/16-bit ppg0 cycle setting buffer register ch.1 r/w 11111111 b 0fa2 h pds11 8/16-bit ppg1 duty setting buffer register ch.1 r/w 11111111 b 0fa3 h pds10 8/16-bit ppg0 duty setting buffer register ch.1 r/w 11111111 b 0fa4 h ppgs 8/16-bit ppg starting register r/w 00000000 b 0fa5 h revc 8/16-bit ppg output inversion register r/w 00000000 b 0fa6 h to 0fa9 h ? (disabled) ?? 0faa h pdcrh0 16-bit ppg down counter re gister (upper byte) ch.0 r 00000000 b 0fab h pdcrl0 16-bit ppg down counter regi ster (lower byte) ch.0 r 00000000 b 0fac h pcsrh0 16-bit ppg cycle setting buffer register (upper byte) ch.0 r/w 11111111 b 0fad h pcsrl0 16-bit ppg cycle setting buffer register (lower byte) ch.0 r/w 11111111 b 0fae h pduth0 16-bit ppg duty setting buffer re gister (upper byte) ch.0 r/w 11111111 b 0faf h pdutl0 16-bit ppg duty setting buffer re gister (lower byte) ch.0 r/w 11111111 b
mb95110h series 24 (continued) r/w access symbols initial value symbols note : do not write to the ? (disabled) ?. re ading the ? (disabled) ? returns an undefined value. address register abbreviation register name r/w initial value 0fb0 h to 0fbb h ? (disabled) ?? 0fbc h bgr1 lin-uart baud rate gene rator register 1 r/w 00000000 b 0fbd h bgr0 lin-uart baud rate gene rator register 0 r/w 00000000 b 0fbe h pssr0 uart/sio dedicated baud rate generator prescaler selection register ch.0 r/w 00000000 b 0fbf h brsr0 uart/sio dedicated baud rate generator baud rate setting register ch.0 r/w 00000000 b 0fc0 h to 0fc2 h ? (disabled) ?? 0fc3 h aidrl a/d input disable register (lower byte) r/w 00000000 b 0fc4 h to 0fe2 h ? (disabled) ?? 0fe3 h wcdr watch counter data register r/w 00111111 b 0fe4 h to 0fed h ? (disabled) ?? 0fee h ilsr input level select register r/w 00000000 b 0fef h wicr interrupt pin control register r/w 01000000 b 0ff0 h to 0fff h ? (disabled) ?? r/w : readable/writable r : read only w : write only 0 : the initial value of this bit is ?0?. 1 : the initial value of this bit is ?1?. x : the initial value of this bit is undefined.
mb95110h series 25 interrupt source table interrupt source interrupt request number vector table address bit name of interrupt level setting register same level priority order (at simultaneous occurrence) upper lower external interrupt ch.0 irq0 fffa h fffb h l00 [1 : 0] high low external interrupt ch.4 external interrupt ch.1 irq1 fff8 h fff9 h l01 [1 : 0] external interrupt ch.5 external interrupt ch.2 irq2 fff6 h fff7 h l02 [1 : 0] external interrupt ch.6 external interrupt ch.3 irq3 fff4 h fff5 h l03 [1 : 0] external interrupt ch.7 uart/sio ch.0 irq4 fff2 h fff3 h l04 [1 : 0] 8/16-bit compound timer ch.0 (lower) irq5 fff0 h fff1 h l05 [1 : 0] 8/16-bit compound timer ch.0 (upper) irq6 ffee h ffef h l06 [1 : 0] lin-uart (reception) irq7 ffec h ffed h l07 [1 : 0] lin-uart (transmission) irq8 ffea h ffeb h l08 [1 : 0] 8/16-bit ppg ch.1 (lower) irq9 ffe8 h ffe9 h l09 [1 : 0] 8/16-bit ppg ch.1 (upper) irq10 ffe6 h ffe7 h l10 [1 : 0] (unused) irq11 ffe4 h ffe5 h l11 [1 : 0] 8/16-bit ppg ch.0 (upper) irq12 ffe2 h ffe3 h l12 [1 : 0] 8/16-bit ppg ch.0 (lower) irq13 ffe0 h ffe1 h l13 [1 : 0] 8/16-bit compound timer ch.1 (upper) irq14 ffde h ffdf h l14 [1 : 0] 16-bit ppg ch.0 irq15 ffdc h ffdd h l15 [1 : 0] i 2 c ch.0 irq16 ffda h ffdb h l16 [1 : 0] (unused) irq17 ffd8 h ffd9 h l17 [1 : 0] 8/10-bit a/d converter irq18 ffd6 h ffd7 h l18 [1 : 0] timebase timer irq19 ffd4 h ffd5 h l19 [1 : 0] watch timer/counter irq20 ffd2 h ffd3 h l20 [1 : 0] (unused) irq21 ffd0 h ffd1 h l21 [1 : 0] 8/16-bit compound timer ch.1 (lower) irq22 ffce h ffcf h l22 [1 : 0] flash memory irq23 ffcc h ffcd h l23 [1 : 0]
mb95110h series 26 electrical characteristics 1. absolute maximum ratings (continued) parameter symbol rating unit remarks min max power supply voltage* 1 vcc avcc vss ? 0.3 vss + 6.0 v *2 input voltage* 1 v i vss ? 0.3 vss + 6.0 v *3 output voltage* 1 v o vss ? 0.3 vss + 6.0 v *3 maximum clamp current i clamp ? 2.0 + 2.0 ma applicable to pins* 4 total maximum clamp current |i clamp | ? 20 ma applicable to pins* 4 ?l? level maximum output current i ol1 ? 15 ma other than p00 to p07 i ol2 15 p00 to p07 ?l? level average current i olav1 ? 4 ma other than p00 to p07 average output current = operating current operating ratio (1 pin) i olav2 12 p00 to p07 average output current = operating current operating ratio (1 pin) ?l? level total maximum output current i ol ? 100 ma ?l? level total average output current i olav ? 50 ma total average output current = operating current operating ratio (total of pins) ?h? level maximum output current i oh1 ? ? 15 ma other than p00 to p07 i oh2 ? 15 p00 to p07 ?h? level average current i ohav1 ? ? 4 ma other than p00 to p07 average output current = operating current operating ratio (1 pin) i ohav2 ? 8 p00 to p07 average output current = operating current operating ratio (1 pin) ?h? level total maximum output current i oh ? ? 100 ma ?h? level total average output current i ohav ? ? 50 ma total average output current = operating current operating ratio (total of pins)
mb95110h series 27 (continued) *1 : the parameter is based on av ss = v ss = 0.0 v. *2 : apply equal potential to avcc and vcc. *3 : v i and vo should not exceed v cc + 0.3 v. v i must not exceed the rating voltage. however, if the maximum current to/from an input is limited by some m eans with external components, the i clamp rating supersedes the v i rating. *4 : applicable to pins : p00 to p07, p10 to p15, p20 to p24, p30 to p37, p60 to p67 ? use within recommended operating conditions. ? use at dc voltage (current). ? + b signal is an input signal that exceeds v cc voltage. the + b signal should always be applied a limiting resistance placed between the + b signal and the microcontroller. ? the value of the limiting resistance should be set so that when the + b signal is applied the input current to the microcontroller pin does no t exceed rated values, either instantaneously or for prolonged periods. ? note that when the microcontroller drive current is low, such as in the powe r saving modes, the +b input potential may pass through the protective diode and increase the potential at the v cc pin, and this affects other devices. ? note that if the + b signal is inputted when the mi crocontroller power supply is of f (not fixed at 0 v), the power supply is provided from the pins, so that incomplete operation may result. ? note that if the + b input is applied during power-on, the powe r supply is provided from the pins and the resulting power supply voltage may not be su fficient to operate the power-on reset. ? care must be taken not to leave the + b input pin open. ? sample recommended circuits : warning: semiconductor devices can be permanently dam aged by application of stress (voltage, current, temperature, etc.) in excess of absolute maximum ratings. do not exceed these ratings. parameter symbol rating unit remarks min max power consumption pd ? 320 mw operating temperature t a ? 40 + 85 c storage temperature tstg ? 55 + 150 c p-c h n-c h vcc r ? input/output equivalent circuits + b input (0 v to 16 v) limiting resistance protective diode
mb95110h series 28 2. recommended operating conditions (avss = vss = 0.0 v) (continued) parameter symbol pin name condi- tions value unit remarks min max power supply voltage v cc , av cc ?? 2.5* 1 5.5 v in normal operation mb95117h mb95f118hs/ 118ts/ mb95f118hw/ 118tw 2.3 5.5 v hold condition in stop mode 2.7 5.5 v in normal operation mb95fv100b- 103 2.3 5.5 v hold condition in stop mode ?h? level input voltage v ih1 p10, p67 *2 0.7 vcc vcc + 0.3 v at selecting of cmos input level v ih2 p50, p51 *2 0.7 vcc vss + 5.5 v at selecting of cmos input level v ihs1 p00 to p07, p10 to p15, p20 to p24, p30 to p37, p60 to p67, pg1* 3 , pg2* 3 *2 0.8 vcc vcc + 0.3 v hysteresis input v ihs2 p50, p51 *2 0.8 vcc vss + 5.5 v hysteresis input v ihm rst , mod ? 0.7 vcc vcc + 0.3 v cmos input (flash memory product) ? 0.8 vcc vcc + 0.3 v hysteresis input (mask rom product) ?l? level input voltage v il p10, p50, p51, p67 *2 vss ? 0.3 0.3 vcc v at selecting of cmos input level v ils p00 to p07, p10 to p15, p20 to p24, p30 to p37, p50, p51, p60 to p67, pg1* 3 , pg2* 3 *2 vss ? 0.3 0.2 vcc v hysteresis input v ilm rst , mod ? vss ? 0.3 0.3 vcc v cmos input (flash memory product) ? vss ? 0.3 0.2 vcc v hysteresis input (mask rom product)
mb95110h series 29 (continued) (avss = vss = 0.0 v) *1 : the value is 2.9 v when the lo w voltage detection reset is used. *2 : p10, p50, p51, and p67 can switch the input level to either the ?cmos inpu t level? or ?hysteresis input level?. the switching of the input level can be set by the input level selection register (ilsr). *3 : single clock products only *4 : use a ceramic capacitor or a capacitor with equiva lent frequency characteristics. a bypass capacitor of v cc pin must have a capacitance value higher than c s . for connection of smoothing capacitor c s , see the diagram below. warning: the recommended operating conditions are require d in order to ensure the normal operation of the semiconductor device. all of the device?s electr ical characteristics are warranted when the device is operated within these ranges. always use semiconductor devices within their recommended operating cond ition ranges. operation outside these ranges may adversely affect re liability and could result in device failure. no warranty is made with respect to uses, operat ing conditions, or combinations not represented on the data sheet. users considering application outside the listed conditions are advised to contact their fujitsu representatives beforehand. parameter symbol pin name condi- tions value unit remarks min max smoothing capacitor c s ?? 0.1 1.0 f*4 operating temperature t a ?? ? 40 + 85 c mb95117h mb95f118hs/118ts/ mb95f118hw/118tw + 5 + 35 c mb95fv100b-103 c c s c pin connection diagram
mb95110h series 30 3. dc characteristics (vcc = avcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) (continued) parameter sym- bol pin name conditions value unit remarks min typ max ?h? level output voltage v oh1 output pin other than p00 to p07 i oh = ? 4.0 ma 4.0 ?? v v oh2 p00 to p07 i oh = ? 8.0 ma 4.0 ?? v ?l? level output voltage v ol1 output pin other than p00 to p07 i ol = 4.0 ma ?? 0.4 v v ol2 p00 to p07 i ol = 12 ma ?? 0.4 v open-drain out- put application voltage v d p50, p51 ? vss ? 0.3 ? vss + 5.5 v input leakage current (hi-z output leakage current) i li port other than p50, p51 0.0 v < v i < vcc ? 5 ? + 5 a when the pull- up prohibition setting open-drain out- put leakage current i liod p50, p51 0.0 v < v i < vss + 5.5 v ?? 5 a pull-up resistor r pull p10 to p15, p20 to p24, p30 to p37, pg1* 1 , pg2* 1 v i = 0.0 v 25 50 100 k ? when the pull- up permission setting pull-down resistor r mod mod v i = vcc 25 50 100 k ? mask rom product
mb95110h series 31 (vcc = avcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) (continued) parameter sym bol pin name conditions value unit remarks min typ max power supply current* 2 i cc vcc (external clock operation) v cc = 5.5 v f ch = 20 mhz f mp = 10 mhz main clock mode (divided by 2) ? 9.5 12.5 ma flash memory product (at other than flash memory writing and erasing) ? 30 35 ma flash memory product (at flash memory writing and erasing) ? 7.2 9.5 ma mask rom product i ccs v cc = 5.5 v f ch = 20 mhz f mp = 10 mhz main sleep mode (divided by 2) ? 4.5 7.5 ma i ccl v cc = 5.5 v f cl = 32 khz f mpl = 16 khz sub clock mode (divided by 2) , t a = + 25 c ? 45 100 a i ccls v cc = 5.5 v f cl = 32 khz f mpl = 16 khz sub sleep mode (divided by 2) , t a = + 25 c ? 10 81 a
mb95110h series 32 (continued) (vcc = avcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : single clock product only *2 : ? the power-supply current is determined by the external clock. when low voltage detection option is selected, the power-supply current will be a va lue of adding current consumption of the low voltage detection circuit (i lv d ) to the specified value. ? refer to ?4. ac characteristics (1) clock timing? for f ch and f cl . ? refer to ?4. ac characteristics (2) source clock/machine clock? for f mp and f mpl . parameter sym- bol pin name conditions value unit remarks min typ max power supply current* 2 i cct v cc (external clock operation) * 2 v cc = 5.5 v f cl = 32 khz watch mode main stop mode t a = + 25 c ? 4.6 27 a i ccmpll v cc = 5.5 v f ch = 4 mhz f mp = 10 mhz main pll mode (multiplied by 2.5) ? 9.3 12.5 ma flash memory product ? 7.0 9.5 ma mask rom product i ccspll v cc = 5.5 v f cl = 32 khz f mpl = 128 khz sub pll mode (multiplied by 4) t a = + 25 c ? 160 400 a i cts v cc = 5.5 v f ch = 10 mhz timebase timer mode t a = + 25 c ? 0.15 1.10 ma i cch v cc = 5.5 v sub stop mode t a = + 25 c ? 520 a main stop mode for single clock product i lvd v cc current consumption for low voltage detection circuit only ? 38 50 a i a avcc v cc = 5.5 v f ch = 10 mhz at operating of a/d conversion ? 2.4 4.7 ma i ah v cc = 5.5 v f ch = 10 mhz at stopping a/d conversion t a = + 25 c ? 15 a input capacitance c in other than avcc, avss, vcc, vss f = 1 mhz ? 515pf
mb95110h series 33 4. ac characteristics (1) clock timing (vcc = 2.5 v to 5.5 v, avss = vss = 0.0 v, t a = ? 40 c to + 85 c) parameter sym- bol pin name condi- tions value unit remarks min typ max clock frequency f ch x0, x1 ? 1 ? 10 mhz when using main oscillation circuit 1 ? 20 mhz when using external clock 3 ? 10 mhz main pll multiplied by 1 3 ? 5 mhz main pll multiplied by 2 3 ? 4 mhz main pll multiplied by 2.5 f cl x0a, x1a ? 32.768 ? khz when using sub oscillation circuit ? 32.768 ? khz when using sub pll v cc = 2.3 v to 3.6 v clock cycle time t hcyl x0, x1 100 ? 1000 ns when using main oscillation circuit 50 ? 1000 ns when using external clock t lcyl x0a, x1a ? 30.5 ? s when using sub oscilla- tion circuit input clock pulse width t wh1 t wl1 x0 10 ?? ns when using external clock duty ratio is about 30 % to 70 % . t wh2 t wl2 x0a ? 15.2 ? s input clock rise time and fall time t cr t cf x0, x0a ?? 5 ns when using external clock
mb95110h series 34 t hcyl t wh1 t cr 0.2 v cc x 0 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc t cf t wl1 x0 x1 f ch x0 f ch x1 ? figure of main clock input port external connection when using a crystal or ceramic oscillator when using external clock open microcontroller microcontroller t lcyl t wh2 t cr 0.1 v cc x 0a 0.8 v cc 0.8 v cc 0.1 v cc 0.1 v cc t cf t wl2 x0a x1a f cl x0a f cl x1a ? figure of sub clock input port external connection when using a crystal or ceramic oscillator when using external clock open microcontroller microcontroller
mb95110h series 35 (2) source clock/machine clock (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : clock before setting division due to machine clock divi sion ratio selection bit (sycc : div1 and div0) . this source clock is divided by the machine clock divisi on ratio selection bit (sycc : div1 and div0) , and it becomes the machine clock. further, the s ource clock can be selected as follows. ? main clock divided by 2 ? pll multiplication of main clock (sel ect from 1, 2, 2.5 multiplication) ? sub clock divided by 2 ? pll multiplication of sub clock (sel ect from 2, 3, 4 multiplication) * 2 : operation clock of the microcontroller. machine clock can be selected as follows. ? source clock (no division) ? source clock divided by 4 ? source clock divided by 8 ? source clock divided by 16 parameter sym- bol pin name value unit remarks min typ max source clock cycle time* 1 (clock before setting division) t sclk ? 100 ? 2000 ns when using main clock min : f ch = 10 mhz, pll multiplied by 1 max : f ch = 1 mhz, divided by 2 7.6 ? 61.0 s when using sub clock min : f cl = 32 khz, pll multiplied by 4 max : f cl = 32 khz, divided by 2 source clock frequency f sp ? 0.5 ? 10.0 mhz when using main clock f spl ? 16.384 ? 131.072 khz when using sub clock machine clock cycle time* 2 (minimum instruction execution time) t mclk ? 100 ? 32000 ns when using main clock min : f sp = 10 mhz, no division max : f sp = 0.5 mhz, divided by 16 7.6 ? 976.5 s when using sub clock min : f spl = 131 khz, no division max : f spl = 16 khz, divided by 16 machine clock frequency f mp ? 0.031 ? 10.000 mhz when using main clock f mpl 1.024 ? 131.072 khz when using sub clock f ch ( main oscillation) f cl (sub oscillation) devided by 2 main pll 1 2 2.5 devided by 2 sub pll 2 3 4 sclk ( source clock ) mclk ( machine clock ) clock mode select bit ( sycc : scs1, scs0 ) division circuit 1 1/4 1/8 1/16 ? outline of clock generation block
mb95110h series 36 10 mhz 0.5 mhz 2.5 3 mhz 5.5 131.072 khz 16.384 khz 2.5 32 khz 5.5 10 mh z 4 mhz 3 mhz 5 mhz 6 mhz 7 mhz 8 mhz 9 mhz 3 mhz 4 mhz 5 mhz 6 mhz 7 mhz 8 mhz 9 mhz 10 mhz 7 .5 mhz ? main pll operation frequency main clock frequency ( f mp ) source clock frequency (f sp ) 2.5 2 1 operating voltage (v) source clock frequency (f spl ) main clock operating guarantee range sub pll operating guarantee range sub clock mode, watch mode, operating guarantee range main clock mode, main pll mode, operating guarantee range pll operating guarantee range pll operating guarantee range operating voltage (v) source clock frequency (f sp ) ? operating voltage ? operating frequency ( t a = ? 40 c to + 85 c) ? mb95f118hs, mb95f118ts , mb95f118hw, mb95f118tw ? operating voltage ? operating frequency ( t a = + 5 c to + 35 c) ? mb95fv100b-103 10 mhz 0.5 mhz 2.7 3 mhz 5.5 131.072 khz 16.384 khz 2.7 32 khz 5.5 source clock frequency (f spl ) operating voltage (v) sub pll, sub clock mode and watch mode operation guarantee range pll operation guarantee range source clock frequency (f sp ) operating voltage (v) pll operation guarantee range main clock operati on guarantee range main clock mode and main pll mode operation guarantee range
mb95110h series 37 (3) external reset (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : refer to ? (2) source clock/machine clock? for t mclk . *2 : oscillation start time of oscillator is the time that the amplitude reaches 90 %. in the crystal oscillator, the oscillation time is between several ms and tens of ms. in ceramic oscillators, the oscillation time is between hundreds of s and several ms. in the external clock, the oscillation time is 0 ms. parameter symbol value unit remarks min max rst ?l? level pulse width t rstl 2 t mclk * 1 ? ns at normal operating oscillation time of oscillator* 2 + 100 ? s at stop mode, sub clock mode, sub sleep mode, and watch mode 100 ? s at timebase timer mode t rstl 0.2 v cc rst 0.2 v cc t rstl 0.2 v cc 0.2 v cc 100 s r st x 0 ? at normal operating ? at stop mode, sub clock mode, sub sleep mode, and watch mode, and power-on internal operating clock internal reset 90 % of amplitude oscillation time of oscillator oscillation stabilization wait time execute instruction
mb95110h series 38 (4) power-on reset (avss = vss = 0.0 v, t a = ? 40 c to + 85 c) note : sudden change of power suppl y voltage may activate the power-on reset function. wh en changing power supply voltages during operation, set the slope of rising within 30 mv/ms as shown below. parameter symbol conditions value unit remarks min max power supply rising time t r ?? 50 ms power supply cutoff time t off ? 1 ? ms waiting time until power-on 0.2 v 0.2 v t off t r 2.5 v 0.2 v v cc v cc 2.3 v v ss hold condition in stop mode limiting the slope of rising within 30 mv/ms is recommended.
mb95110h series 39 (5) peripheral input timing (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) * : refer to ? (2) source clock/machine clock? for t mclk . parameter symbol pin name value unit remarks min max peripheral input ?h? pulse width t ilih int00 to int07, ec0, ec1, trg0/adtg 2 t mclk * ? ns peripheral input ?l? pulse width t ihil 2 t mclk * ? ns t ilih i nt00 to int07, e c0, ec1, trg0/adtg 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc t ihil
mb95110h series 40 (6) uart/sio, serial i/o timing (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) * : refer to ? (2) source clock/machine clock? for t mclk . parameter symbol pin name conditions value unit remarks min max serial clock cycle time t scyc uck0 internal clock operation output pin: c l = 80 pf + 1ttl. 4 t mclk * ? ns uck uo time t slov uck0, uo0 ? 190 + 190 ns valid ui uck t ivsh uck0, ui0 2 t mclk * ? ns uck valid ui hold time t shix uck0, ui0 2 t mclk * ? ns serial clock ?h? pulse width t shsl uck0 external clock operation output pin: c l = 80 pf + 1ttl. 4 t mclk * ? ns serial clock ?l? pulse width t slsh uck0 4 t mclk * ? ns uck uo time t slov uck0, uo0 ? 190 ns valid ui uck t ivsh uck0, ui0 2 t mclk * ? ns uck valid ui hold time t shix uck0, ui0 2 t mclk * ? ns t scyc t ivsh 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc t shix t slov 0.8 v 2.4 v 0.8 v 2.4 v u ck0 u o0 u i0 0.8 v t slsh t ivsh 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc t shix t slov 0.2 v cc 0.2 v cc 0.8 v cc 0.8 v cc t shsl 2.4 v u ck0 u o0 u i0 0.8 v internal shift clock mode external shift clock mode
mb95110h series 41 (7) lin-uart timing sampling at the rising edge of sampling clock *1 and prohibited serial clock delay *2 (escr register : sces bit = 0, eccr register : scde bit = 0) (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : provide switch function whether sampling of reception data is performed at rising edge or falling edge of the serial clock. *2 : serial clock delay function is used to delay half clock for the output signal of serial clock. *3 : refer to ? (2) source clock/machine clock? for t mclk . parameter sym- bol pin name conditions value unit min max serial clock cycle time t scyc sck internal clock operation output pin : c l = 80 pf + 1 ttl. 5 t mclk * 3 ? ns sck sot delay time t slovi sck, sot ? 95 + 95 ns valid sin sck t ivshi sck, sin t mclk * 3 + 190 ? ns sck valid sin hold time t shixi sck, sin 0 ? ns serial clock ?l? pulse width t slsh sck external clock operation output pin : c l = 80 pf + 1 ttl. 3 t mclk * 3 ? t r ? ns serial clock ?h? pulse width t shsl sck t mclk * 3 + 95 ? ns sck sot delay time t slove sck, sot ? 2 t mclk * 3 + 95 ns valid sin sck t ivshe sck, sin 190 ? ns sck valid sin hold time t shixe sck, sin t mclk * 3 + 95 ? ns sck fall time t f sck ? 10 ns sck rise time t r sck ? 10 ns
mb95110h series 42 0.8 v 0.8 v 2.4 v t slovi t ivshi t shixi 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc 2.4 v 0.8 v s ck s ot s in t scyc t slove t ivshe t shixe 0.8 v cc 0.8 v cc 0.8 v cc 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc 0.2 v cc 0.2 v cc 2.4 v 0.8 v t r t f s ck s ot s in t slsh t shsl internal shift clock mode external shift clock mode
mb95110h series 43 sampling at the falling edge of sampling clock *1 and prohibited serial clock delay *2 (escr register : sces bit = 1, eccr register : scde bit = 0) (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : provide switch function whether sampling of receptio n data is performed at rising edge or falling edge of the serial clock. *2 : serial clock delay function is used to delay half clock for the output signal of serial clock. *3 : refer to ? (2) source clock/machine clock? for t mclk . parameter sym- bol pin name conditions value unit min max serial clock cycle time t scyc sck internal clock operation output pin : c l = 80 pf + 1 ttl. 5 t mclk * 3 ? ns sck sot delay time t shovi sck, sot ? 95 + 95 ns valid sin sck t ivsli sck, sin t mclk * 3 + 190 ? ns sck valid sin hold time t slixi sck, sin 0 ? ns serial clock ?h? pulse width t shsl sck external clock operation output pin : c l = 80 pf + 1 ttl. 3 t mclk * 3 ? t r ? ns serial clock ?l? pulse width t slsh sck t mclk * 3 + 95 ? ns sck sot delay time t shove sck, sot ? 2 t mclk * 3 + 95 ns valid sin sck t ivsle sck, sin 190 ? ns sck valid sin hold time t slixe sck, sin t mclk * 3 + 95 ? ns sck fall time t f sck ? 10 ns sck rise time t r sck ? 10 ns
mb95110h series 44 0.8 v 2.4 v 2.4 v t shovi t ivsli t slixi 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc 2.4 v 0.8 v s ck s ot s in t scyc t shove t ivsle t slixe 0.8 v cc 0.8 v cc 0.8 v cc 0.8 v cc 0.2 v cc 0.2 v cc 0.2 v cc 0.2 v cc 0.2 v cc 2.4 v 0.8 v t f t r s ck s ot s in t shsl t slsh internal shift clock mode external shift clock mode
mb95110h series 45 sampling at the rising edge of sampling clock *1 and enabled serial clock delay *2 (escr register : sces bit = 0, eccr register : scde bit = 1) (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : provide switch function whether sampling of reception data is performed at rising edge or falling edge of the serial clock. *2 : serial clock delay function is used to delay half clock for the output signal of serial clock. *3 : refer to ? (2) source clock/machine clock? for t mclk . parameter sym- bol pin name conditions value unit min max serial clock cycle time t scyc sck internal clock operation output pin : c l = 80 pf + 1 ttl. 5 t mclk * 3 ? ns sck sot delay time t shovi sck, sot ? 95 + 95 ns valid sin sck t ivsli sck, sin t mclk * 3 + 190 ? ns sck valid sin hold time t slixi sck, sin 0 ? ns sot sck delay time t sovli sck, sot ? 4 t mclk * 3 ns s ck s ot s in 2.4 v 0.8 v 0.8 v t shovi 2.4 v 0.8 v 0.8 v cc 0.2 v cc 0.8 v cc 0.2 v cc 2.4 v 0.8 v t scyc t sovli t ivsli t slixi
mb95110h series 46 sampling at the falling edge of sampling clock *1 and enabled serial clock delay *2 (escr register : sces bit = 1, eccr register : scde bit = 1) (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : provide switch function whether sampling of receptio n data is performed at rising edge or falling edge of the serial clock. *2 : serial clock delay function is used to delay half clock for the output signal of serial clock. *3 : refer to ? (2) source clock/machine clock? for t mclk . parameter sym- bol pin name conditions value unit min max serial clock cycle time t scyc sck internal clock operating output pin : c l = 80 pf + 1 ttl. 5 t mclk * 3 ? ns sck sot delay time t slovi sck, sot ? 95 + 95 ns valid sin sck t ivshi sck, sin t mclk * 3 + 190 ? ns sck valid sin hold time t shixi sck, sin 0 ? ns sot sck delay time t sovhi sck, sot ? 4 t mclk * 3 ns s ck s ot s in 2.4 v 2.4 v 0.8 v t slovi 2.4 v 0.8 v 0.8 v cc 0.2 v cc 0.8 v cc 0.2 v cc 2.4 v 0.8 v t scyc t sovhi t ivshi t shixi
mb95110h series 47 (8) i 2 c timing (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : r, c : pull-up resistor and load capacitor of the scl and sda lines. *2 : the maximum t hd;dat have only to be met if the device dose not stretch the ?l? width (t low ) of the scl signal. *3 : a fast-mode i 2 c-bus device can be used in a standard-mode i 2 c-bus system, but the requirement t su;dat 250 ns must then be met. parameter symbol pin name conditions value unit remarks standard- mode fast-mode min max min max scl clock frequency f scl scl0 r = 1.7 k ? , c = 50 pf* 1 0 100 0 400 khz (repeat) start condition hold time sda scl t hd;sta scl0 sda0 4.0 ? 0.6 ? s scl clock ?l? width t low scl0 4.7 ? 1.3 ? s scl clock ?h? width t high scl0 4.0 ? 0.6 ? s (repeat) start condition setup time scl sda t su;sta scl0 sda0 4.7 ? 0.6 ? s data hold time scl sda t hd;dat scl0 sda0 0 3.45* 2 00.9* 3 s data setup time sda scl t su;dat scl0 sda0 0.25 ? 0.1 ? s stop condition setup time scl sda t su;sto scl0 sda0 4 ? 0.6 ? s bus free time between stop condition and start condition t buf scl0 sda0 4.7 ? 1.3 ? s s da0 s cl0 t wakeup t hd;sta t su;dat t hd;sta t su;sta t low t hd;dat t high t su;sto t buf
mb95110h series 48 (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) (continued) parameter sym- bol pin name condition value* 2 unit remarks min max scl clock ?l? width t low scl0 r = 1.7 k ? , c = 50 pf* 1 (2 + nm / 2) t mclk ? 20 ? ns master mode scl clock ?h? width t high scl0 (nm / 2) t mclk ? 20 (nm / 2 ) t mclk + 20 ns master mode start condition hold time t hd;sta scl0 sda0 ( ? 1 + nm / 2) t mclk ? 20 ( ? 1 + nm) t mclk + 20 ns master mode maximum value is applied when m, n = 1, 8. otherwise, the minimum value is applied. stop condition setup time t su;sto scl0 sda0 (1 + nm / 2) t mclk ? 20 (1 + nm / 2) t mclk + 20 ns master mode start condition setup time t su;sta scl0 sda0 (1 + nm / 2) t mclk ? 20 (1 + nm / 2) t mclk + 20 ns master mode bus free time between stop condition and start condition t buf scl0 sda0 (2 nm + 4) t mclk ? 20 ? ns data hold time t hd;dat scl0 sda0 3 t mclk ? 20 ? ns master mode data setup time t su;dat scl0 sda0 ( ? 2 + nm / 2) t mclk ? 20 ( ? 1 + nm / 2) t mclk + 20 ns master mode when assuming that ?l? of scl is not extended, the minimum value is applied to first bit of continuous data. otherwise, the maximum value is applied. setup time between clearing interrupt and scl rising t su;int scl0 (nm / 2) t mclk ? 20 (1 + nm / 2) t mclk + 20 ns minimum value is applied to interrupt at 9th scl . maximum value is applied to interrupt at 8th scl . scl clock ?l? width t low scl0 4 t mclk ? 20 ? ns at reception scl clock ?h? width t high scl0 4 t mclk ? 20 ? ns at reception start condition detection t hd;sta scl0 sda0 2 t mclk ? 20 ? ns undetected when 1 t mclk is used at reception stop condition detection t su;sto scl0 sda0 2 t mclk ? 20 ? ns undetected when 1 t mclk is used at reception restart condition detection condition t su;sta scl0 sda0 2 t mclk ? 20 ? ns undetected when 1 t mclk is used at reception bus free time t buf scl0 sda0 2 t mclk ? 20 ? ns at reception data hold time t hd;dat scl0 sda0 2 t mclk ? 20 ? ns at slave transmission mode data setup time t su;dat scl0 sda0 t low ? 3 t mclk ? 20 ? ns at slave transmission mode
mb95110h series 49 (continued) (vcc = 5.0 v 10 % , avss = vss = 0.0 v, t a = ? 40 c to + 85 c) *1 : r, c : pull-up resistor and load capacitor of the scl and sda lines. *2 : ? refer to ? (2) source clock/machine clock? for t mclk . ? m is cs4 bit and cs3 bit (bit 4 and bit 3) of clock control register (iccr) . ? n is cs2 bit to cs0 bit (bit 2 to bit 0) of clock control register (iccr) . ? actual timing of i 2 c is determined by m and n valu es set by the machine clock (t mclk ) and cs4 to cs0 of iccr0 register. ? standard-mode : m and n can be set at the range : 0.9 mhz < t mclk (machine clock) < 10 mhz. setting of m and n limits the machin e clock that can be used below. (m, n) = (1, 8) : 0.9 mhz < t mclk 1 mhz (m, n) = (1, 22) , (5, 4) , (6, 4) , (7, 4) , (8, 4) : 0.9 mhz < t mclk 2 mhz (m, n) = (1, 38) , (5, 8) , (6, 8) , (7, 8) , (8, 8) : 0.9 mhz < t mclk 4 mhz (m, n) = (1, 98) : 0.9 mhz < t mclk 10 mhz ? fast-mode : m and n can be set at the range : 3.3 mhz < t mclk (machine clock) < 10 mhz. setting of m and n limits the machine clock that can be used below. (m, n) = (1, 8) : 3.3 mhz < t mclk 4 mhz (m, n) = (1, 22) , (5, 4) : 3.3 mhz < t mclk 8 mhz (m, n) = (6, 4) : 3.3 mhz < t mclk 10 mhz parameter sym- bol pin name condition value* 2 unit remarks min max data hold time t hd;dat scl0 sda0 r = 1.7 k ? , c = 50 pf* 1 0 ? ns at reception data setup time t su;dat scl0 sda0 t mclk ? 20 ? ns at reception sda scl (at wake-up function) t wakeup scl0 sda0 oscillation stabilization wait time + 2 t mclk ? 20 ? ns
mb95110h series 50 (9) low voltage detection (avss = vss = 0.0 v, t a = ? 40 c to + 85 c) parameter symbol value unit remarks min typ max release voltage v dl+ 2.55 2.70 2.85 v at power-supply rise detection voltage v dl- 2.45 2.60 2.75 v at power-supply fall hysteresis width v hys 70 100 ? mv power-supply start voltage v off ?? 2.3 v power-supply end voltage v on 4.9 ?? v power-supply voltage change time (at power supply rise) t r 0.3 ?? s slope of power supply that reset release signal generates ? 3000 ? s slope of power supply that reset release signal generates within rating (v dl+ ) power-supply voltage change time (at power supply fall) t f 300 ?? s slope of power supply that reset detection signal generates ? 300 ? s slope of power supply that reset detection signal generates within rating (v dl- ) reset release delay time t d1 ?? 400 s reset detection delay time t d2 ?? 30 s current consumption i lvd ? 38 50 a current consumption for low voltage detection circuit only v hys t d2 t d1 t r t f v cc v cc v on v off v dl+ v dl- internal reset signal time
mb95110h series 51 5. a/d converter (1) a/d converter electrical characteristics (avcc = vcc = 4.0 v to 5.5 v, avss = vss = 0.0 v, t a = ? 40 c to + 85 c) parameter symbol value unit remarks min typ max resolution ? ?? 10 bit total error ? 3.0 ? + 3.0 lsb linearity error ? 2.5 ? + 2.5 lsb differential linear error ? 1.9 ? + 1.9 lsb zero transition voltage v ot avss ? 1.5 lsb avss + 0.5 lsb avss + 2.5 lsb v full-scale transition voltage v fst avcc ? 3.5 lsb avcc ? 1.5 lsb avcc + 0.5 lsb v compare time ? 0.9 ? 16500 s4.5 v avcc 5.5 v 1.8 ? 16500 s4.0 v avcc < 4.5 v sampling time ? 0.6 ?? s 4.5 v avcc 5.5 v, at external impedance < 5.4 k ? 1.2 ?? s 4.0 v avcc < 4.5 v, at external impedance < 2.4 k ? analog input current i ain ? 0.3 ? + 0.3 a analog input voltage v ain avss ? avcc v reference voltage ? avss + 4.0 ? avcc v avcc pin reference voltage supply current i r ? 600 900 a avcc pin, during a/d operation i rh ?? 5 a avcc pin, at stop mode
mb95110h series 52 (2) notes on using a/d converter ? about the external impedance of analog input and its sampling time a/d converter with sample and hold circuit. if the exter nal impedance is too high to keep sufficient sampling time, the analog voltage charged to the internal sample a nd hold capacitor is insufficient, adversely affecting a/ d conversion precision, therefore, to satisfy the a/d conversion precision standard, consider the relationship between the external impedance and minimum sampling time and either adjust the register value and operating frequency or decrease the external impedance so that the sampling time is longer than the minimum value. also, if the sampling time cannot be suffic ient, connect a capacitor of about 0.1 f to the analog input pin. ? about errors as |av cc ? av ss | becomes smaller, values of relative errors grow larger. r c analog input note : the values are reference values. ? analog input equivalent circuit rc 4.5 v avcc 5.5 v 2.0 k ? (max) 16 pf (max) 4.0 v avcc < 4.5 v 8.2 k ? (max) 16 pf (max) comparator during sampling : on 0 2 46 8 10 12 1 4 0 10 20 30 40 50 60 70 80 90 1 00 av cc 4.5 v av cc 4.0 v 0123 4 0 2 4 6 8 1 0 1 2 1 4 1 6 1 8 2 0 av cc 4.5 v av cc 4.0 v (external impedance = 0 k ? to 100 k ? ) (external impedance = 0 k ? to 20 k ? ) minimum sampling time [ s] external impedance [k ? ] minimum sampling time [ s] external impedance [k ? ] ? the relationship between external impedance and minimum sampling time
mb95110h series 53 (3) definition of a/d converter terms resolution the level of analog variation that can be distinguished by the a/d converter. when the number of bits is 10, anal og voltage can be divided into 2 10 = 1024. linearity error (unit : lsb) the deviation between the value along a straig ht line connecting the zero transition point (?00 0000 0000? ?00 0000 0001?) of a device and the full-scale transition point (?11 1111 1111? ?11 1111 1110?) compared with the actual conversion values obtained. differential linear error (unit : lsb) deviation of input voltage, which is required for changing output code by 1 lsb, from an ideal value. total error (unit: lsb) difference between actual and theoretical values, caused by a zero transition error, full-scale transition error, linearity error, quantum error, and noise. (continued) v fst 1.5 lsb 3 ff h 3 fe h 3 fd h 004 h 003 h 002 h 001 h 3ff h 3fe h 3fd h 004 h 003 h 002 h 001 h 1 lsb 0.5 lsb v ot av ss av ss av cc av c c v nt {1 lsb ( n ? 1 ) + 0.5 lsb} 1 lsb = avcc ? avss 1024 (v) total error of digital output n v nt ? {1 lsb (n ? 1) + 0.5 lsb} 1 lsb ideal i/o characteristics total error digital output analog input analog input digital output [lsb] actual conversion characteristic actual conversion characteristic ideal characteristics n : a/d converter digital output value v nt : a voltage at which digital output transits from (n ? 1) to n. =
mb95110h series 54 (continued) av ss av ss av ss v nt av ss av cc av cc av cc av c c 001 h 002 h 003 h 004 h 3fc h 3fd h 3fe h 3ff h 001 h 002 h 003 h 004 h 3 fd h 3 fe h 3ff h n - 2 n - 1 n n + 1 {1 lsb n + v ot } v nt v ( n + 1 ) t full-scale transition error digital output actual conversion characteristic actual conversion characteristic ideal characteristics analog input v fst (measurement value) zero transition error digital output actual conversion characteristic actual conversion characteristic analog input v ot (measurement value) ? 1 differential linear error in digital output n v (n + 1) t ? v nt 1 lsb linearity error in digital output n v nt ? {1 lsb n + v ot } 1 lsb linearity error digital output actual conversion characteristic actual conversion characteristic analog input ideal characteristics differential linear error digital output actual conversion characteristic actual conversion characteristic analog input ideal characteristics v fst (measurement value) v ot (measurement value) n : a/d converter digital output value v nt : a voltage at which digital output transits from (n ? 1) to n. v ot (ideal value) = av ss + 0.5 lsb [v] v fst (ideal value) = av cc ? 1.5 lsb [v] ideal characteristics = =
mb95110h series 55 6. flash memory program/erase characteristics *1 : t a = + 25 c, v cc = 5.0 v, 10000 cycles *2 : t a = + 85 c, v cc = 4.5 v, 10000 cycles *3 : this value comes from the technology qualification (using arrhenius equation to translate high temperature measurements into normalized value at + 85 c) . parameter value unit remarks min typ max sector erase time (4 kbytes sector) ? 0.2* 1 0.5* 2 s excludes 00 h programming prior erasure. sector erase time (16 kbytes sector) ? 0.5* 1 7.5* 2 s excludes 00 h programming prior erasure. byte programming time ? 32 3600 s excludes system-level overhead. program/erase cycle 10000 ?? cycle power supply voltage at program/erase 4.5 ? 5.5 v flash memory data retention time 20* 3 ?? year average t a = + 85 c
mb95110h series 56 example characteristics ? mb95117h power supply current (external clock) (continued) 2 i cc [ma] v cc [v] 10 9 8 7 6 5 4 3 2 1 0 345 6 i cc - v cc ta = +25 c f mclk = 1, 5, 10 mhz 2 i ccs [ma] v cc [v] 5 4.5 4 3.5 3 2.5 2 1.5 1 0.5 0 3456 i ccs - v cc ta = +25 c f mpll = 1, 5, 10 mhz 2 i ccmpll [ma] v cc [v] 10 9 8 7 6 5 4 3 2 1 0 3456 i ccmpll - v cc ta = +25 c f mpll = 1, 5, 10 mhz 2 i ccl [ a] v cc [v] 100 90 80 70 60 50 40 30 20 10 0 3456 i ccl - v cc ta = +25 c f cl = 32 khz 2 i ccls [ a] v cc [v] 20 18 16 14 12 10 8 6 4 2 0 3456 i ccls - v cc ta = +25 c f cl = 32 khz 2 i cct [ a] v cc [v] 10 9 8 7 6 5 4 3 2 1 0 3456 i cct - v cc ta = +25 c f cl = 32 khz 2 i ccspll [ a] v cc [v] 100 90 80 70 60 50 40 30 20 10 0 3456 i ccspll - v cc ta = +25 c f cl = 32 khz
mb95110h series 57 (continued) ? mb95117h power supply current temperature 2 i cts [ma] v cc [v] 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 3456 i cts - v cc ta = +25 c f mclk = 5 mhz 2 i cch [ a] v cc [v] 345 6 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 i cch - v cc ta = +25 c f cl = 32 khz ? 50 i cc [ma] i cc [ma] ta [ c] 16 14 12 10 8 6 4 2 0 0 +50 +100 +150 ? 50 i cc [ma] i cc [ma] ta [ c] 8 7 6 5 4 3 2 1 0 0 +50 +100 +150 ? 50 i ccs [ma] i ccs [ma] ta [ c] 0 +50 +100 +150 8 7 6 5 4 3 2 1 0 ? 50 i ccs [ma] i ccs [ma] ta [ c] 4 3.5 3 2.5 2 1.5 1 0.5 0 0 +50 +100 +150 power supply current (main clock mode divided by 2) (vcc = 5.5 v, f ch = 21 mhz, external clock) power supply current (main clock mode divided by 32) (vcc = 5.5 v, f ch = 21 mhz, external clock) power supply current (main sleep mode divided by 2) (vcc = 5.5 v, f ch = 21 mhz, external clock) power supply current (main sl eep mode divided by 32) (vcc = 5.5 v, f ch = 21 mhz, external clock)
mb95110h series 58 ? mb95117h input voltage ? mb95117h output voltage hysteresis input 2 v in [v] v cc [v] 5 4.5 4 3.5 3 2 1 2.5 1.5 0.5 0 3456 ta = + 25 c vcc = 3.0 [v ] vcc = 3.5 [v ] vcc = 2.7 [v] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] i oh [ma] vcc ? v oh 1 [v] 1.4 1.2 1 0.8 0.6 0.4 0.2 0 0 ? 1 ? 2 ? 3 ? 4 ? 5 ? 6 ? 7 ? 8 ? 9 ? 10 vcc = 3.0 [v ] vcc = 3.5 [v ] vcc = 2.7 [v ] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] i oh [ma] vcc ? v oh 2 [v] 0.6 0.5 0.4 0.3 0.2 0.1 0 0 ? 1 ? 2 ? 3 ? 4 ? 5 ? 6 ? 7 ? 8 ? 9 ? 10 vcc = 3.5 [v ] vcc = 2.7 [v] vcc = 3.0 [v] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] i oh [ma] v ol 1 [v] 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 012345678910 vcc = 3.5 [v ] vcc = 3.0 [v ] vcc = 2.7 [v ] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] i oh [ma] v ol 2 [v] 0.4 0.35 0.3 0.25 0.2 0.15 0.1 0.05 0 012345678910 v oh 1-i oh (ta = + 25 c) v oh 2-i oh (ta = + 25 c) v ol 1-i oh (ta = + 25 c) v ol 2-i oh (ta = + 25 c)
mb95110h series 59 ? mb95f118h power supply current (external clock) (continued) 0 1 2 3 4 5 6 7 8 9 10 26 5 4 3 i cc [ma] v cc [v] i cc - v cc ta = +25 c f mclk = 1, 5, 10 mhz 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 24 6 5 3 i ccs [ma] v cc [v] i ccs - v cc ta = +25 c f mpll = 1, 5, 10 mh z 0 1 2 3 4 5 6 7 8 9 10 256 4 3 i ccmpll [ma] v cc [v] i ccmpll - v cc ta = +25 c f mpll = 1, 5, 10 mhz 0 10 20 30 40 50 60 70 80 90 100 25 34 6 i ccl [ a] v cc [v] i ccl - v cc ta = +25 c f cl = 32 khz 0 2 4 6 8 10 12 14 16 18 20 25 34 6 i ccls [ a] v cc [v] i ccls - v cc ta = +25 c f cl = 32 khz 0 1 2 3 4 5 6 7 8 9 10 25 34 6 i cct [ a] v cc [v] i cct - v cc ta = +25 c f cl = 32 khz 0 10 20 30 40 50 60 70 80 90 100 246 35 i ccspll [ a] v cc [v] i ccspll - v cc ta = +25 c f cl = 32 khz
mb95110h series 60 (continued) ? mb95f118h power supply current temperature 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 246 35 i cts [ma] v cc [v] i cts - v cc ta = +25 c f mpll = 5 mhz 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 i cch [ a] v cc [v] i cch - v cc ta = +25 c f cl = 32 khz 246 35 0 2 4 6 8 10 12 14 16 ? 50 0 + 50 + 100 + 150 ta [ c ] i cc [ma] i cc [ma] 0 1 2 3 4 5 6 7 8 ? 50 0 + 50 + 100 + 150 ta [ c ] i cc [ma] i cc [ma] 0 1 2 3 4 5 6 7 8 ? 50 0 + 50 + 100 + 150 ta [ c ] i ccs [ma] i ccs [ma] 0 0.5 1 1.5 2 2.5 3 3.5 4 ? 50 0 + 50 + 100 + 150 ta [ c ] i ccs [ma] i ccs [ma] power supply current (main clock mode divided by 2) (vcc = 5.5 v, f ch = 21 mhz, external clock) power supply current (main clock mode divided by 32) (vcc = 5.5 v, f ch = 21 mh, external clock) power supply current (main clock mode divided by 2) (vcc = 5.5 v, f ch = 21 mhz, external clock) power supply current (main clock mode divided by 32) (vcc = 5.5 v, f ch = 21 mhz, external clock)
mb95110h series 61 ? mb95f118h input voltage ? mb95f118h output voltage hysteresis input 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 23456 v in [v] v cc [v] ta = + 25 c 0 0.2 0.4 0.6 0.8 1 1.2 1.4 ? 10 ? 9 ? 8 ? 7 ? 6 ? 5 ? 4 ? 3 ? 2 ? 1 0 i oh [ma] vcc-v oh 1 [v] vcc = 3.5 [v ] vcc = 3.0 [v] vcc = 2.7 [v] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] 0 0.1 0.2 0.3 0.4 0.5 0.6 ? 10 ? 9 ? 8 ? 7 ? 6 ? 5 ? 4 ? 3 ? 2 ? 1 0 i oh [ma] vcc-v oh 2 [v] vcc = 3.5 [v ] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] vcc = 3.0 [v] vcc = 2.7 [v] 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 i oh [ma] v ol 1 [v] vcc = 3.5 [v ] vcc = 3.0 [v] vcc = 2.7 [v] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] 02 5 910 8 7 6 4 3 1 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 i oh [ma] v ol 2 [v] vcc = 2.7 [v ] vcc = 3.0 [v ] vcc = 3.5 [v ] vcc = 4.0 [v ] vcc = 4.5 [v ] vcc = 5.0 [v ] vcc = 5.5 [v ] vcc = 6.0 [v ] 02 5 910 8 7 6 4 3 1 v oh 1-i oh (ta = + 25 c) v oh 2-i oh (ta = + 25 c) v ol 1-i oh (ta = + 25 c) v ol 2-i oh (ta = + 25 c)
mb95110h series 62 mask option * : refer to table below about clock mode select , low voltage detection reset and reset output. no. part number mb95117h mb95f118hs mb95f118ts mb95f118hw mb95f118tw mb95fv100b-103 specifying procedure setting disabled setting disabled setting disabled setting disabled 1 clock mode select ? single-system clock mode ? dual-system clock mode specify when ordering mask single-system clock mode dual-system clock mode changing by the switch on mcu board 2 low voltage detection reset* ? with low voltage detection reset ? without low voltage detection reset specify when ordering mask specified by part number specified by part number changing by the switch on mcu board 3 oscillation stabilization wait time fixed to oscillation stabilization wait time of (2 14 ? 2) /f ch fixed to oscilla- tion stabilization wait time of (2 14 ? 2) /f ch fixed to oscilla- tion stabilization wait time of (2 14 ? 2) /f ch fixed to oscillation stabilization wait time of (2 14 ? 2) /f ch part number clock mode select low voltage detection reset reset output mb95117h single-system no yes yes yes dual-system no yes yes yes mb95f118hs single-system no yes mb95f118ts yes yes mb95f118hw dual-system no yes mb95f118tw yes yes mb95fv100b-103 single-system no yes yes yes dual-system no yes yes yes
mb95110h series 63 ordering information part number package remarks MB95117HPMC mb95f118hspmc mb95f118hwpmc mb95f118tspmc mb95f118twpmc 52-pin plastic lqfp (fpt-52p-m01) mb2146-303 (mb95fv100b-103pbt) mcu board ( ) 224-pin plastic pfbga (bga-224p-m08)
mb95110h series 64 package dimensions 52-pin pl as tic lqfp le a d pitch 0.65 mm p a ck a ge width p a ck a ge length 10.0 10.0 mm le a d s h a pe gullwing s e a ling method pl as tic mold mounting height 1.70 mm m a x code (reference) p-lqfp52-10 10-0.65 52-pin pl as tic lqfp (fpt-52p-m01) (fpt-52p-m01) lead no. det a il s of "a" p a rt 0.25(.010) ( s t a nd off) (.004 .004) 0.10 0.10 (.024 .006) 0.60 0.15 (.020 .00 8 ) 0.50 0.20 1.50 +0.20 ? 0.10 +.00 8 ? .004 .059 0 ? ~ 8 ? "a" 0.10(.004) (.006 .002) 0.145 0.055 0.1 3 (.005) m 0.65(.026) 12.00 0.20(.472 .00 8 ) s q 10.00 0.10(. 3 94 .004) s q index 40 52 27 3 9 14 26 1 3 1 2005 fujit s u limited f52001 s -c-1-1 c (mounting height) .012 ? .0014 +.0027 ? 0.0 3 5 +0.065 0. 3 0 * dimen s ion s in mm (inche s ). note: the v a lue s in p a renthe s e s a re reference v a lue s note 1) * : the s e dimen s ion s do not include re s in protru s ion. note 2) pin s width a nd pin s thickne ss include pl a ting thickne ss . note 3 ) pin s width do not include tie ba r cutting rem a inder.
mb95110h series f0607 the information for microcontroller supports is shown in the following homepage. http://www.fujitsu.com/global/services/mic roelectronics/product/micom/support/index.html fujitsu limited all rights reserved. the contents of this document are subject to change without notice. customers are advised to consult with fujitsu sales representatives before ordering. the information, such as descriptions of function and application circuit examples, in this document are presented solely for the purpose of reference to show examples of operations and uses of fujitsu semiconductor device; fujitsu does not warrant proper operation of the device with respect to use based on such information. when you develop equipment incorporating the device based on such information, you must assume any responsibility arising out of such use of the information. fujitsu assumes no liability for any damages whatsoever arising out of the use of the information. any information in this document, including descriptions of function and schematic diagrams, shall not be construed as license of the use or exercise of any intellectual property right, such as patent right or copyright, or any ot her right of fujitsu or any third party or does fujitsu warrant non-in fringement of any third-party?s intellectual property right or othe r right by using such information. fujitsu assumes no liability for any infringement of the intellectual property rights or other rights of third parties which would result from the use of information contained herein. the products described in this document are designed, developed and manufactured as contemplated for general use, including without limitation, ordinary industrial use, general office use, personal use, and household use, but are not designed, developed and manufactured as contemplated (1) for use accompanying fatal risks or dangers that, unless extremel y high safety is secured, could have a serious effect to the public, and could lead directly to death, personal injury, severe physical damage or other loss (i.e., nuclear reaction control in nuclear facility, ai rcraft flight control, air traffic control, mass transport control, medical life support system, missile launch control in weapon syst em), or (2) for use requiring extremely high reliability (i.e., su bmersible repeater and artificial satellite). please note that fujitsu will not be liable against you and/or any third party for any claims or damages arising in connection with above-mentioned uses of the products. any semiconductor devices have an inherent chance of failure. you must protect against injury, damage or loss from such failures by incorporating safety design m easures into your facility and equipment such as redundancy, fi re protection, and prevention of over-current levels and other abnormal operating conditions. if any products described in this document represent goods or technologies subject to certain restrictions on export under the foreign exchange and foreign trade law of japan, the prior authorization by japanese government will be required for export of those products from japan. edited business promotion dept.

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