View AT89C51ED2_1479964.PDF datasheet online --- IC-ON-LINE

Datasheet File OCR Text:

rev. 4235d?8051?12/03 1 features 80c52 compatible ? 8051 instruction compatible ? six 8-bit i/o ports (64 pins or 68 pins versions) ? four 8-bit i/o ports (44 pins version) ? three 16-bit timer/counters ? 256 bytes scratch pad ram ? 9 interrupt sources with 4 priority levels integrated power monitor (por/pfd) to supervise internal power supply isp (in-system programming) using standard v cc power supply boot rom contains low level flash programming routines and a default serial loader high-speed architecture ? in standard mode: 40 mhz (vcc 2.7v to 5.5v, both internal and external code execution) 60 mhz (vcc 4.5v to 5.5v and internal code execution only) ? in x2 mode (6 clocks/machine cycle) 20 mhz (vcc 2.7v to 5.5v, both internal and external code execution) 30 mhz (vcc 4.5v to 5.5v and internal code execution only) 64k bytes on-chip flash program/data memory ? byte and page (128 bytes) erase and write ? 100k write cycles on-chip 1792 bytes expanded ram (xram) ? software selectable size (0, 256, 512, 768, 1024, 1792 bytes) ? 768 bytes selected at reset for t89c51rd2 compatibility on-chip 2048 bytes eeprom block for data storage (AT89C51ED2 only) ? 100k write cycles dual data pointer variable length movx for slow ram/peripherals improved x2 mode with independent selection for cpu and each peripheral keyboard interrupt interface on port 1 spi interface (master/slave mode) 8-bit clock prescaler 16-bit programmable counter array ? high speed output ?compare/capture ? pulse width modulator ? watchdog timer capabilities asynchronous port reset full-duplex enhanced uart with dedicated internal baud rate generator low emi (inhibit ale) hardware watchdog timer (one-time enabled with reset-out), power-off flag power control modes: idle mode, power-down mode single range power supply: 2.7v to 5.5v industrial temperature range (-40 to +85 c) packages: plcc44, vqfp44, plcc68, vqfp64, pdil40 description at89c51rd2/ed2 is high performance cmos flash version of the 80c51 cmos sin- gle chip 8-bit microcontroller. it contains a 64-kbyte flash memory block for code and for data. the 64-kbytes flash memory can be programmed either in parallel mode or in serial mode with the isp capability or with software. the programming voltage is internally generated from the standard v cc pin. 8-bit flash microcontroller at89c51rd2 AT89C51ED2
2 at89c51rd2/ed2 4235d?8051?12/03 the at89c51rd2/ed2 retains all of the features of the atmel 80c52 with 256 bytes of internal ram, a 9-source 4-level interrupt controller and three timer/counters. the AT89C51ED2 provides 2048 bytes of eeprom for nonvolatile data storage. in addition, the at89c51rd2/ed2 has a programmable counter array, an xram of 1792 bytes, a hardware watchdog timer, spi interface, keyboard, a more versatile serial channel that facilitates multiprocessor communication (euart) and a speed improvement mechanism (x2 mode). the fully static design of the at89c51rd2/ed2 allows to reduce system power con- sumption by bringing the clock frequency down to any value, including dc, without loss of data. the at89c51rd2/ed2 has 2 software-selectable modes of reduced activity and an 8- bit clock prescaler for further reduction in power consumption. in the idle mode the cpu is frozen while the peripherals and the interrupt system are still operating. in the power- down mode the ram is saved and all other functions are inoperative. the added features of the at89c51rd2/ed2 make it more powerful for applications that need pulse width modulation, high speed i/o and counting capabilities such as alarms, motor control, corded phones, and smart card readers. table 1. memory size and i/o pins package flash (bytes) xram (bytes) total ram (bytes) i/o plcc44/vqfp44/dil40 64k 1792 2048 34 plcc68/vqfp64 64k 1792 2048 50
3 at89c51rd2/ed2 4235d?8051?12/03 block diagram figure 1. block diagram timer 0 int ram 256x8 t0 t1 rxd txd wr rd ea psen ale/ xtala2 xtala1 euart cpu timer 1 int1 ctrl int0 (2) (2) c51 core (2) (2) (2) (2) port 0 p0 port 1 port 2 port 3 p1 p2 p3 xram 1792 x 8 ib-bus pca reset prog watch -dog pca eci vss vcc (2) (2) (1) (1): alternate function of port 1 (2): alternate function of port 3 (1) timer2 t2ex t2 (1) (1) flash 64k x 8 keyboard (1) keyboard miso mosi sck ss port4 p4 (1) (1) (1) (1) boot 2k x 8 rom regulator por / pfd port 5 p5 parallel i/o ports & external bus spi eeprom* 2k x 8 (AT89C51ED2)
5 at89c51rd2/ed2 4235d?8051?12/03 sfr mapping the special function registers (sfrs) of the at89c51rd2/ed2 fall into the following categories: c51 core registers: acc, b, dph, dpl, psw, sp i/o port registers: p0, p1, p2, p3, pi2 timer registers: t2con, t2mod, tcon, th0, th1, th2, tmod, tl0, tl1, tl2, rcap2l, rcap2h serial i/o port registers: saddr, saden, sbuf, scon pca (programmable counter array) registers: ccon, ccapmx, cl, ch, ccapxh, ccapxl (x: 0 to 4) power and clock control registers: pcon hardware watchdog timer registers: wdtrst, wdtprg interrupt system registers: ie0, ipl0, iph0, ie1, ipl1, iph1 keyboard interface registers: kbe, kbf, kbls spi registers: spcon, spstr, spdat brg (baud rate generator ) registers: brl, bdrcon clock prescaler register: ckrl others: auxr, auxr1, ckcon0, ckcon1
6 at89c51rd2/ed2 4235d?8051?12/03 table 2. c51 core sfrs mnemonicaddname 76543210 acc e0h accumulator b f0h b register psw d0h program status word cy ac f0 rs1 rs0 ov f1 p sp 81h stack pointer dpl 82h data pointer low byte dph 83h data pointer high byte table 3. system management sfrs mnemonicaddname 76543210 pcon 87h power control smod1 smod0 - pof gf1 gf0 pd idl auxr 8eh auxiliary register 0 dpu - m0 xrs2 xrs1 xrs0 extram ao auxr1 a2h auxiliary register 1 - - enboot -gf30 -dps ckrl 97hclock reload register -------- ckckon0 8fh clock control register 0 - wdtx2 pcax2 six2 t2x2 t1x2 t0x2 x2 ckckon1afhclock control register 1 -------spix2 table 4. interrupt sfrs mnemonicaddname 76543210 ien0 a8h interrupt enable control 0 ea ec et2 es et1 ex1 et0 ex0 ien1 b1hinterrupt enable control 1 -----espi kbd iph0 b7h interrupt priority control high 0 - ppch pt2h phs pt1h px1h pt0h px0h ipl0 b8h interrupt priority control low 0 - ppcl pt2l pls pt1l px1l pt0l px0l iph1 b3hinterrupt priority control high 1-----spih kbdh ipl1 b2hinterrupt priority control low 1-----spil kbdl table 5. port sfrs mnemonicaddname 76543210 p0 80h 8-bit port 0 p1 90h 8-bit port 1 p2 a0h 8-bit port 2 p3 b0h 8-bit port 3 p4 c0h 8-bit port 4
7 at89c51rd2/ed2 4235d?8051?12/03 p5 d8h 8-bit port 5 p5 c7h 8-bit port 5 (byte addressable) table 5. port sfrs mnemonicaddname 76543210 table 6. timer sfrs mnemonicaddname 76543210 tcon 88h timer/counter 0 and 1 control tf1 tr1 tf0 tr0 ie1 it1 ie0 it0 tmod 89h timer/counter 0 and 1 modes gate1 c/t1# m11 m01 gate0 c/t0# m10 m00 tl0 8ah timer/counter 0 low byte th0 8ch timer/counter 0 high byte tl1 8bh timer/counter 1 low byte th1 8dh timer/counter 1 high byte wdtrst a6h watchdog timer reset wdtprga7hwatchdog timer program -----wto2wto1wto0 t2con c8h timer/counter 2 control tf2 exf2 rclk tclk exen2 tr2 c/t2# cp/rl2# t2mod c9h timer/counter 2 mode ------t2oedcen rcap2h cbh timer/counter 2 reload/capture high byte rcap2l cah timer/counter 2 reload/capture low byte th2 cdh timer/counter 2 high byte tl2 cch timer/counter 2 low byte table 7. pca sfrs mnemo -nicaddname 76543210 ccon d8h pca timer/counter control cf cr ccf4 ccf3 ccf2 ccf1 ccf0 cmod d9h pca timer/counter mode cidl wdte cps1 cps0 ecf cl e9h pca timer/counter low byte ch f9h pca timer/counter high byte ccapm0 ccapm1 ccapm2 ccapm3 ccapm4 dah dbh dch ddh deh pca timer/counter mode 0 pca timer/counter mode 1 pca timer/counter mode 2 pca timer/counter mode 3 pca timer/counter mode 4 ecom0 ecom1 ecom2 ecom3 ecom4 capp0 capp1 capp2 capp3 capp4 capn0 capn1 capn2 capn3 capn4 mat0 mat1 mat2 mat3 mat4 tog0 tog1 tog2 tog3 tog4 pwm0 pwm1 pwm2 pwm3 pwm4 eccf0 eccf1 eccf2 eccf3 eccf4
8 at89c51rd2/ed2 4235d?8051?12/03 ccap0h ccap1h ccap2h ccap3h ccap4h fah fbh fch fdh feh pca compare capture module 0 h pca compare capture module 1 h pca compare capture module 2 h pca compare capture module 3 h pca compare capture module 4 h ccap0h7 ccap1h7 ccap2h7 ccap3h7 ccap4h7 ccap0h6 ccap1h6 ccap2h6 ccap3h6 ccap4h6 ccap0h5 ccap1h5 ccap2h5 ccap3h5 ccap4h5 ccap0h4 ccap1h4 ccap2h4 ccap3h4 ccap4h4 ccap0h3 ccap1h3 ccap2h3 ccap3h3 ccap4h3 ccap0h2 ccap1h2 ccap2h2 ccap3h2 ccap4h2 ccap0h1 ccap1h1 ccap2h1 ccap3h1 ccap4h1 ccap0h0 ccap1h0 ccap2h0 ccap3h0 ccap4h0 ccap0l ccap1l ccap2l ccap3l ccap4l eah ebh ech edh eeh pca compare capture module 0 l pca compare capture module 1 l pca compare capture module 2 l pca compare capture module 3 l pca compare capture module 4 l ccap0l7 ccap1l7 ccap2l7 ccap3l7 ccap4l7 ccap0l6 ccap1l6 ccap2l6 ccap3l6 ccap4l6 ccap0l5 ccap1l5 ccap2l5 ccap3l5 ccap4l5 ccap0l4 ccap1l4 ccap2l4 ccap3l4 ccap4l4 ccap0l3 ccap1l3 ccap2l3 ccap3l3 ccap4l3 ccap0l2 ccap1l2 ccap2l2 ccap3l2 ccap4l2 ccap0l1 ccap1l1 ccap2l1 ccap3l1 ccap4l1 ccap0l0 ccap1l0 ccap2l0 ccap3l0 ccap4l0 table 8. serial i/o port sfrs mnemonicaddname 76543210 scon 98h serial control fe/sm0 sm1 sm2 ren tb8 rb8 ti ri sbuf 99h serial data buffer saden b9h slave address mask saddr a9h slave address bdrcon 9bh baud rate control brr tbck rbck spd src brl 9ah baud rate reload table 7. pca sfrs (continued) mnemo -nicaddname 76543210 table 9. spi controller sfrs mnemonicaddname 76543210 spcon c3h spi control spr2 spen ssdis mstr cpol cpha spr1 spr0 spsta c4h spi status spif wcol sserr modf spdat c5h spi data spd7 spd6 spd5 spd4 spd3 spd2 spd1 spd0 table 10. keyboard interface sfrs mnemonicaddname 76543210 kbls 9ch keyboard level selector kbls7 kbls6 kbls5 kbls4 kbls3 kbls2 kbls1 kbls0 kbe 9dh keyboard input enable kbe7 kbe6 kbe5 kbe4 kbe3 kbe2 kbe1 kbe0 kbf 9eh keyboard flag register kbf7 kbf6 kbf5 kbf4 kbf3 kbf2 kbf1 kbf0 table 11. eeprom data memory sfr (AT89C51ED2 only) mnemonicaddname 76543210 eecon d2h eeprom data control eee eebusy
9 at89c51rd2/ed2 4235d?8051?12/03 table 12 shows all sfrs with their address and their reset value. table 12. sfr mapping bit addressable non bit addressable 0/8 1/9 2/a 3/b 4/c 5/d 6/e 7/f f8h pi2 xxxx xx11 ch 0000 0000 ccap0h xxxx xxxx ccap1h xxxx xxxx ccap2h xxxx xxxx ccap3h xxxx xxxx ccap4h xxxx xxxx ffh f0h b 0000 0000 f7h e8h p5 bit addressable 1111 1111 cl 0000 0000 ccap0l xxxx xxxx ccap1l xxxx xxxx ccap2l xxxx xxxx ccap3l xxxx xxxx ccap4l xxxx xxxx efh e0h acc 0000 0000 e7h d8h ccon 00x0 0000 cmod 00xx x000 ccapm0 x000 0000 ccapm1 x000 0000 ccapm2 x000 0000 ccapm3 x000 0000 ccapm4 x000 0000 dfh d0h psw 0000 0000 fcon xxxx 0000 eecon xxxx xx00 d7h c8h t2con 0000 0000 t2mod xxxx xx00 rcap2l 0000 0000 rcap2h 0000 0000 tl2 0000 0000 th2 0000 0000 cfh c0h p4 1111 1111 spcon 0001 0100 spsta 0000 0000 spdat xxxx xxxx p5 byte addressable 1111 1111 c7h b8h ipl0 x000 000 saden 0000 0000 bfh b0h p3 1111 1111 ien1 xxxx x000 ipl1 xxxx x000 iph1 xxxx x111 iph0 x000 0000 b7h a8h ien0 0000 0000 saddr 0000 0000 ckcon1 xxxx xxx0 afh a0h p2 1111 1111 auxr1 0xxx x0x0 wdtrst xxxx xxxx wdtprg xxxx x000 a7h 98h scon 0000 0000 sbuf xxxx xxxx brl 0000 0000 bdrcon xxx0 0000 kbls 0000 0000 kbe 0000 0000 kbf 0000 0000 9fh 90h p1 1111 1111 ckrl 1111 1111 97h 88h tcon 0000 0000 tmod 0000 0000 tl0 0000 0000 tl1 0000 0000 th0 0000 0000 th1 0000 0000 auxr xx00 1000 ckcon0 0000 0000 8fh 80h p0 1111 1111 sp 0000 0111 dpl 0000 0000 dph 0000 0000 pcon 00x1 0000 87h 0/8 1/9 2/a 3/b 4/c 5/d 6/e 7/f reserved
10 at89c51rd2/ed2 4235d?8051?12/03 pin configurations figure 2. pin configurations 43 42 41 40 39 44 38 37 36 35 34 p1.4/cex1 p1.0/t2 p1.1/t2ex/ss p1.3/cex0 p1.2/eci vcc p0.0/ad0 p0.2/ad2 p0.3/ad3 p0.1/ad1 p0.4/ad4 p0.6/ad6 p0.5/ad5 p0.7/ad7 ale/prog psen ea p2.7/a15 p2.5/a13 p2.6/a14 p1.5/cex2/miso p1.6/cex3/sck p1.7/cex4/mosi rst p3.0/rxd p3.1/txd p3.2/int0 p3.3/int1 p3.4/t0 p3.5/t1 p3.6/wr p3.7/rd xtal2 xtal1 vss p2.0/a8 p2.1/a9 p2.2/a10 p2.3/a11 p2.4/a12 nic* 12 13 17 16 15 14 20 19 18 21 22 33 32 31 30 29 28 27 26 25 24 23 at89c51rd2/ed2 1 2 3 4 5 6 7 8 9 10 11 vqfp44 1.4 nic* nic* nic* plcc44 at89c51rd2/ed2 nic* nic* nic* pdil40 p1.7cex4/mosi p1.4/cex1 rst p3.0/rxd p3.1/txd p1.3cex0 1 p1.5/cex2/miso p1.6/cex3/sck p3.2/int0 p3.3/int1 p3.4/t0 p3.5/t1 p3.6/wr p3.7/rd xtal2 xtal1 vss p2.0/ad8 p2.1/ad9 p2.2/ad10 p2.3/ad11 p2.4/ad12 p0.4/ad4 p0.6/ad6 p0.5/ad5 p0.7/ad7 ale/prog psen ea p2.7/ad15 p2.5/ad13 p2.6/ad14 p1.0/t2 p1.2/eci p1.1/t2ex/ss vcc p0.0/ad0 p0.1/ad1 p0.2/ad2 p0.3/ad3 AT89C51ED2 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 18 19 23 22 21 20 26 25 24 27 28 5 4 3 2 1 6 44 43 42 41 40 p1.4/cex1 p1.0/t2 p1.1/t2ex/ss p1.3/cex0 p1.2/eci vcc p0.0/ad0 p0.2/ad2 p0.1/ad1 p0.4/ad4 p0.6/ad6 p0.5/ad5 p0.7/ad7 ale/prog psen ea p2.7/a15 p2.5/a13 p2.6/a14 p3.6/wr p3.7/rd xtal2 xtal1 vss p2.0/a8 p2.1/a9 p2.2/a10 p2.3/a11 p2.4/a12 p1.5/cex2/miso p1.6/cex3/sck p1.7/cex4/mosi rst p3.0/rxd p3.1/txd p3.2/int0 p3.3/int1 p3.4/t0 p3.5/t1 p0.3/ad3 nic* 7 8 9 10 11 12 13 14 15 16 17 39 38 37 36 35 34 33 32 31 30 29
11 at89c51rd2/ed2 4235d?8051?12/03 50 49 48 47 44 45 46 p4.5 p3.7/rd xtal2 xtal1 p4.4 p3.6/wr p4.3 nic nic p3.1/txd p3.2/int0 p3.3/int1 p3.4/t0 p3.5/t1 37 38 39 40 41 42 43 AT89C51ED2 plcc68 p0.4/ad4 p5.4 p5.3 p0.5/ad5 p0.6/ad6 nic p0.7/ad7 ea nic ale p1.6/cex3/sck p1.7/cex4/mosi rst nic nic nic p3.0/rxd nic nic p1.5/cex2/miso 60 59 58 57 56 55 54 53 51 52 10 11 12 13 14 15 16 17 19 18 27 28 29 30 31 32 33 34 35 36 9 8 7 6 5 3 2 1 68 p5.0 p2.4/a12 p2.3/a11 p4.7 p2.2/a10 p4.6 p2.0/a8 p2.1/a9 nic vss p5.5 p0.3/ad3 p0.2/ad2 p5.6 p0.1/ad1 p0.0/ad0 p5.7 vcc nic p1.0/t2 4 psen nic p2.7/a15 p2.6/a14 p5.2 p5.1 p2.5/a13 67 65 64 63 62 61 66 20 21 22 23 26 25 24 p4.0 p1.1/t2ex/ss p1.2/eci p1.3/cex0 p4.1 p1.4/cex1 p4.2 nic: not internaly connected 54 53 52 51 50 49 AT89C51ED2 vqfp64 p0.4/ad4 p5.4 p5.3 p0.5/ad5 p0.6/ad6 p0.7/ad7 ea nic ale psen# p1.5/cex2/miso p1.6/cex3/sck p1.7/a17/cex4/mosi rst nic nic nic p3.0/rxd nic p4.2 48 47 46 45 44 43 42 41 39 40 1 2 3 4 5 6 7 8 10 9 17 18 19 20 21 22 23 24 25 26 64 63 62 61 60 59 58 57 56 55 p2.4/a12 p2.3/a11 p4.7 p2.2/a10 p2.1/a9 nic p4.6 p2.0/a8 vss p4.5 p5.5 p0.3/ad3 p0.2/ad2 p5.6 p0.1/ad1 p0.0/ad0 p5.7 vcc nic p1.0/t2 11 12 13 16 15 14 p4.0 p1.1/t2ex/ss p1.2/eci p1.3/cex0 p4.1 p1.4/cex1 38 37 36 33 34 35 p3.7/rd xtal2 xtal1 p4.4 p3.6/wr p4.3 nic p3.1/txd p3.2/int0 p3.3/int1 p3.4/t0 p3.5/t1 27 28 29 30 31 32 p2.7/a15 p2.6/a14 p5.2 p5.1 p2.5/a13 p5.0
12 at89c51rd2/ed2 4235d?8051?12/03 table 13. pin description mnemonic pin number type name and function plcc44 vqfp44 plcc68 vqfp64 pdil40 v ss 22 16 51 40 20 i ground: 0v reference v cc 44 38 17 8 40 i power supply: this is the power supply voltage for normal, idle and power-down operation p0.0 - p0.7 43 - 36 37 - 30 15, 14, 12, 11, 9,6, 5, 3 6, 5, 3, 2, 64, 61,60,59 i/o port 0 : port 0 is an open-drain, bidirectional i/o port. port 0 pins that have 1s written to them float and can be used as high impedance inputs. port 0 must be polarized to v cc or v ss in order to prevent any parasitic current consumption. port 0 is al so the multiplexed low-order address and data bus during access to external program and data memory. in this application, it uses strong internal pull-up when emitting 1s. port 0 also inputs the code bytes during eprom pr ogramming. external pull-ups are required during program verificati on during which p0 outputs the code bytes. 32-39 p1.0 - p1.7 2 - 9 40 - 44 1 - 3 19, 21, 22, 23, 25, 27, 28, 29 10, 12, 13, 14, 16, 18, 19, 20 1-8 i/o port 1: port 1 is an 8-bit bidirectional i/o port with internal pull-ups. port 1 pins that have 1s written to them ar e pulled high by the internal pull-ups and can be used as inputs. as inputs, port 1 pins that are externally pulled low will source current because of the internal pull-ups. port 1 also receives the low-order address by te during memory programming and verification. alternate functions for at89c51rd2/ed2 port 1 include: 24019 10 1i/o p1.0 : input/output i/o t2 (p1.0): timer/counter 2 external count input/clockout 34121 12 2i/o p1.1: input/output i t2ex: timer/counter 2 reload/capture/direction control i ss : spi slave select 44222 13 3i/o p1.2: input/output i eci: external clock for the pca 54323 14 4i/o p1.3: input/output i/o cex0: capture/compare external i/o for pca module 0 64425 16 5i/o p1.4: input/output i/o cex1: capture/compare external i/o for pca module 1 7 1 27 18 6 i/o p1.5: input/output i/o cex2: capture/compare external i/o for pca module 2 i/o miso: spi master input slave output line when spi is in master mode, miso receives data from the slave periph- eral. when spi is in slave mode, miso outputs data to the master con- troller. 8 2 28 19 7 i/o p1.6: input/output i/o cex3: capture/compare external i/o for pca module 3 i/o sck: spi serial clock
13 at89c51rd2/ed2 4235d?8051?12/03 9 3 29 20 8 i/o p1.7: input/output: i/o cex4: capture/compare external i/o for pca module 4 i/o mosi: spi master output slave input line when spi is in master mode, mosi outputs data to the slave peripheral. when spi is in slave mode, mosi receives data from the master control- ler. xtala1 21 15 49 38 19 i xtala 1: input to the inverting oscillator amplifier and input to the inter- nal clock generator circuits. xtala2 20 14 48 37 18 o xtala 2: output from the inverting oscillator amplifier p2.0 - p2.7 24 - 31 18 - 25 54, 55, 56, 58, 59, 61, 64, 65 43, 44, 45, 47, 48, 50, 53, 54 i/o port 2 : port 2 is an 8-bit bidirectional i/o port with internal pull-ups. port 2 pins that have 1s written to them ar e pulled high by the internal pull-ups and can be used as inputs. as inputs, port 2 pins that are externally pulled low will source current because of the internal pull-ups. port 2 emits the high-order address byte duri ng fetches from external program memory and during accesses to exte rnal data memory that use 16-bit addresses (movx @dptr).in this application, it uses strong internal pull-ups emitting 1s. during accesses to external data memory that use 8-bit addresses (movx @ri), port 2 emits the contents of the p2 sfr. 21-28 p3.0 - p3.7 11, 13 - 19 5, 7 - 13 34, 39, 40, 41, 42, 43, 45, 47 25, 28, 29, 30, 31, 32, 34, 36 10-17 i/o port 3: port 3 is an 8-bit bidirectional i/o port with internal pull-ups. port 3 pins that have 1s written to them ar e pulled high by the internal pull-ups and can be used as inputs. as inputs, port 3 pins that are externally pulled low will source current because of the internal pull-ups. port 3 also serves the special features of the 80c51 family, as listed below. 11 5 34 25 10 i rxd (p3.0): serial input port 13 7 39 28 11 o txd (p3.1): serial output port 14 8 40 29 12 i int0 (p3.2): external interrupt 0 15 9 41 30 13 i int1 (p3.3): external interrupt 1 16 10 42 31 14 i t0 (p3.4): timer 0 external input 17 11 43 32 15 i t1 (p3.5): timer 1 external input 18 12 45 34 16 o wr (p3.6): external data memory write strobe 19 13 47 36 17 o rd (p3.7): external data memory read strobe p4.0 - p4.7 -- 20, 24, 26, 44, 46, 50, 53, 57 11, 15, 17,33, 35,39, 42, 46 -i/o port 4: port 4 is an 8-bit bidirectional i/o port with internal pull-ups. port 3 pins that have 1s written to them ar e pulled high by the internal pull-ups and can be used as inputs. as inputs, port 3 pins that are externally pulled low will source current because of the internal pull-ups. p5.0 - p5.7 -- 60, 62, 63, 7, 8, 10, 13, 16 49, 51, 52, 62, 63, 1, 4, 7 -i/o port 5: port 5 is an 8-bit bidirectional i/o port with internal pull-ups. port 3 pins that have 1s written to them ar e pulled high by the internal pull-ups and can be used as inputs. as inputs, port 3 pins that are externally pulled low will source current because of the internal pull-ups. rst 10 4 30 21 9 i reset: a high on this pin for two machine cycles while the oscillator is running, resets the device. an internal diffused resistor to v ss permits a power-on reset using only an external capacitor to v cc . this pin is an out- put when the hardware watchdog forces a system reset. table 13. pin description (continued) mnemonic pin number type name and function plcc44 vqfp44 plcc68 vqfp64 pdil40
14 at89c51rd2/ed2 4235d?8051?12/03 ale/pro g 33 27 68 56 30 o (i) address latch enable/program pulse: output pulse for latching the low byte of the address during an acce ss to external memory. in normal operation, ale is emitted at a constant rate of 1/6 (1/3 in x2 mode) the oscillator frequency, and can be used for ex ternal timing or clocking. note that one ale pulse is skipped during each access to external data mem- ory. this pin is also the program pulse input (prog ) during flash pro- gramming. ale can be disabled by setting sfr?s auxr.0 bit. with this bit set, ale will be inactive during internal fetches. psen 32 26 67 55 29 o program strobe enable: the read strobe to external program memory. when executing code from the external program memory, psen is acti- vated twice each machine cycle, except that two psen activations are skipped during each access to external data memory. psen is not acti- vated during fetches from internal program memory. ea 35 29 2 58 31 i external access enable: ea must be externally held low to enable the device to fetch code from external program memory locations 0000h to ffffh. if security level 1 is programmed, ea will be internally latched on reset. table 13. pin description (continued) mnemonic pin number type name and function plcc44 vqfp44 plcc68 vqfp64 pdil40
15 at89c51rd2/ed2 4235d?8051?12/03 port types at89c51rd2/ed2 i/o ports (p1, p2, p3, p4, p5) implement the quasi-bidirectional out- put that is common on the 80c51 and most of its derivatives. this output type can be used as both an input and output without the need to reconfigure the port. this is possi- ble because when the port outputs a logic high, it is weakly driven, allowing an external device to pull the pin low. when the pin is pulled low, it is driven strongly and able to sink a fairly large current. these features are somewhat similar to an open drain output except that there are three pull-up transistors in the quasi-bidirectional output that serve different purposes. one of these pull-ups, called the "weak" pull-up, is turned on when- ever the port latch for the pin contains a logic 1. the weak pull-up sources a very small current that will pull the pin high if it is left floating. a second pull-up, called the "medium" pull-up, is turned on when the port latch for the pin contains a logic 1 and the pin itself is also at a logic 1 level. this pull-up provides the primary source current for a quasi-bidi- rectional pin that is outputting a 1. if a pin that has a logic 1 on it is pulled low by an external device, the medium pull-up turns off, and only the weak pull-up remains on. in order to pull the pin low under these conditions, the external device has to sink enough current to overpower the medium pull-up and take the voltage on the port pin below its input threshold. the third pull-up is referred to as the "strong " pull-up. this pull-up is used to speed up low-to-high transitions on a quasi-bidirectional port pin when the port latch changes from a logic 0 to a logic 1. when this occurs, the strong pull-up turns on for a brief time, two cpu clocks, in order to pull the port pin high quickly. then it turns off again. the dpu bit (bit 7 in auxr register) allows to disable the permanent weak pull up of all ports when latch data is logical 0. the quasi-bidirectional port configuration is shown in figure 3. figure 3. quasi-bidirectional output 2 cpu input pin strong medium n weak p clock delay port latch data data dpu auxr.7 pp
16 at89c51rd2/ed2 4235d?8051?12/03 oscillator to optimize the power consumption and exec ution time needed for a specific task, an internal prescaler feature has been implemented between the oscillator and the cpu and peripherals. registers table 14. ckrl register ckrl ? clock reload register (97h) reset value = 1111 1111b not bit addressable table 15. pcon register pcon ? power control register (87h) reset value = 00x1 0000b not bit addressable 76543210 ckrl7 ckrl6 ckrl5 ckrl4 ckrl3 ckrl2 ckrl1 ckrl0 bit number mnemonic description 7:0 ckrl clock reload register prescaler value 76543210 smod1 smod0 - pof gf1 gf0 pd idl bit number bit mnemonic description 7smod1 serial port mode bit 1 set to select double baud rate in mode 1, 2 or 3. 6smod0 serial port mode bit 0 cleared to select sm0 bit in scon register. set to select fe bit in scon register. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4pof power-off flag cleared by software to recognize the next reset type. set by hardware when v cc rises from 0 to its nominal voltage. can also be set by software. 3gf1 general-purpose flag cleared by software for general-purpose usage. set by software for general-purpose usage. 2gf0 general-purpose flag cleared by software for general-purpose usage. set by software for general-purpose usage. 1pd power-down mode bit cleared by hardware when reset occurs. set to enter power-down mode. 0idl idle mode bit cleared by hardware when interrupt or reset occurs. set to enter idle mode.
17 at89c51rd2/ed2 4235d?8051?12/03 functional bloc k diagram figure 4. functional oscillator block diagram prescaler divider a hardware reset puts the prescaler divider in the following state: ckrl = ffh: f clk cpu = f clk periph = f osc /2 (standard c51 feature) any value between ffh down to 00h can be written by software into ckrl register in order to divide frequency of the selected oscillator: ckrl = 00h: minimum frequency f clk cpu = f clk periph = f osc /1020 (standard mode) f clk cpu = f clk periph = f osc /510 (x2 mode) ckrl = ffh: maximum frequency f clk cpu = f clk periph = f osc /2 (standard mode) f clk cpu = f clk periph = f osc (x2 mode) f clk cpu and f clk periph in x2 mode, for ckrl<>0xff: in x1 mode, for ckrl<>0xff then: xtal2 xtal1 osc clk idle cpu clock ckrl reload 8-bit prescaler-divider reset peripheral clock :2 x2 0 1 f osc ckcon0 clk periph cpu ckrl = 0xff? 0 1 f cpu f = clkperiph f osc 2 255 ckrl ? () -------------------------------------------- --- = f cpu f = clkperiph f osc 4 255 ckrl ? () -------------------------------------------- --- =
18 at89c51rd2/ed2 4235d?8051?12/03 enhanced features in comparison to the original 80c52, the at89c51rd2/ed2 implements some new fea- tures, which are : x2 option dual data pointer extended ram programmable counter array (pca) hardware watchdog spi interface 4-level interrupt priority system power-off flag once mode ale disabling some enhanced features are also located in the uart and the timer 2 x2 feature the at89c51rd2/ed2 core needs only 6 clock periods per machine cycle. this feature called ?x2? provides the following advantages: divide frequency crystals by 2 (cheaper crystals) while keeping same cpu power. save power consumption while keeping same cpu power (oscillator power saving). save power consumption by dividing dynamically the operating frequency by 2 in operating and idle modes. increase cpu power by 2 while keeping same crystal frequency. in order to keep the original c51 compatibility, a divider by 2 is inserted between the xtal1 signal and the main clock input of the core (phase generator). this divider may be disabled by software. description the clock for the whole circuit and peripherals is first divided by two before being used by the cpu core and the peripherals. this allows any cyclic ratio to be accepted on xtal1 input. in x2 mode, as this divider is bypassed, the signals on xtal1 must have a cyclic ratio between 40 to 60%. figure 5 shows the clock generation block diagram. x2 bit is validated on the rising edge of the xtal1 2 to avoid glitches when switching from x2 to std mode. figure 6 shows the switching mode waveforms. figure 5. clock generation diagram xtal1 2 ckcon0 x2 8-bit prescaler f osc fxtal 0 1 xtal1:2 f clk cpu f clk periph ckrl
19 at89c51rd2/ed2 4235d?8051?12/03 figure 6. mode switching waveforms the x2 bit in the ckcon0 register (see table 16) allows a switch from 12 clock periods per instruction to 6 clock periods and vice versa. at reset, the speed is set according to x2 bit of hardware security byte (hsb). by default, standard mode is active. setting the x2 bit activates the x2 feature (x2 mode). the t0x2, t1x2, t2x2, uartx2, pcax2, and wdx2 bits in the ckcon0 register (table 16) and spix2 bit in the ckcon1 register (see table 17) allows a switch from standard peripheral speed (12 clock periods per peripheral clock cycle) to fast peripheral speed (6 clock periods per peripheral clock cycle). these bits are active only in x2 mode. xtal1:2 xtal1 cpu clock x2 bit x2 mode std mode std mode f osc
20 at89c51rd2/ed2 4235d?8051?12/03 table 16. ckcon0 register ckcon0 - clock control register (8fh) reset value = 0000 000?hsb. x2?b (see ?hardware security byte?) not bit addressable 76543210 - wdx2 pcax2 six2 t2x2 t1x2 t0x2 x2 bit number bit mnemonic description 7 reserved the values for this bit are indeterminite. do not set this bit. 6wdx2 watchdog clock (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peripheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 5pcax2 programmable counter array clock (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peri pheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 4six2 enhanced uart clock (mode 0 and 2) (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peri pheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 3t2x2 timer2 clock (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peripheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 2t1x2 timer1 clock (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peri pheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 1t0x2 timer0 clock (this control bit is validated when the cpu cloc k x2 is set; when x2 is low, this bit has no effect). cleared to select 6 clock periods per peri pheral clock cycle. set to select 12 clock periods per peripheral clock cycle. 0x2 cpu clock cleared to select 12 clock periods per machine cycle (std mode) for cpu and all the peripherals. set to select 6 clock periods per machine cycle (x2 mode) and to enable the individual peripherals?x2? bits. programmed by hardware after power-up regarding hardware security byte (hsb), default setting, x2 is cleared.
21 at89c51rd2/ed2 4235d?8051?12/03 table 17. ckcon1 register ckcon1 - clock control register (afh) reset value = xxxx xxx0b not bit addressable 76543210 -------spix2 bit number bit mnemonic description 7- reserved 6- reserved 5- reserved 4- reserved 3- reserved 2- reserved 1- reserved 0 spix2 spi (this control bit is validated when the cpu clock x2 is set; when x2 is low, this bit has no effect). clear to select 6 clock periods per peripheral clock cycle. set to select 12 clock periods per peripheral clock cycle.
22 at89c51rd2/ed2 4235d?8051?12/03 dual data pointer register (dptr) the additional data pointer can be used to speed up code exec ution and reduce code size. the dual dptr structure is a way by which the chip will specify the address of an exter- nal data memory location. there are two 16-bit dptr registers that address the external memory, and a single bit called dps = auxr1.0 (see table 18) that allows the program code to switch between them (refer to figure 7). figure 7. use of dual pointer external data memory auxr1(a2h) dps dph(83h) dpl(82h) 0 7 dptr0 dptr1
23 at89c51rd2/ed2 4235d?8051?12/03 table 18. auxr1 register auxr1- auxiliary register 1(0a2h) reset value = xxxx xx0x0b not bit addressable note: 1. bit 2 stuck at 0; this allows to use inc auxr1 to toggle dps without changing gf3. assembly language ; block move using dual data pointers ; modifies dptr0, dptr1, a and psw ; note: dps exits opposite of entry state ; unless an extra inc auxr1 is added ; 00a2 auxr1 equ 0a2h ; 0000 909000mov dptr,#source ; address of source 0003 05a2 inc auxr1 ; switch data pointers 0005 90a000 mov dptr,#dest ; address of dest 0008 loop: 0008 05a2 inc auxr1 ; switch data pointers 000a e0 movx a,@dptr ; get a byte from source 000b a3 inc dptr ; increment source address 000c 05a2 inc auxr1 ; switch data pointers 000e f0 movx @dptr,a ; write the byte to dest 000f a3 inc dptr ; increment dest address 0010 70f6jnz loop ; check for 0 terminator 0012 05a2 inc auxr1 ; (optional) restore dps 76543210 - - enboot - gf3 0 - dps bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6- reserved the value read from this bit is indeterminate. do not set this bit. 5enboot enable boot flash cleared to disable boot rom. set to map the boot rom between f800h - 0ffffh. 4- reserved the value read from this bit is indeterminate. do not set this bit. 3gf3 this bit is a general-purpose user flag. (1) 20 always cleared 1- reserved the value read from this bit is indeterminate. do not set this bit. 0dps data pointer selection cleared to select dptr0. set to select dptr1.
24 at89c51rd2/ed2 4235d?8051?12/03 inc is a short (2 bytes) and fast (12 clocks) way to manipulate the dps bit in the auxr1 sfr. however, note that the inc instruction does not directly force the dps bit to a par- ticular state, but simply toggles it. in simple routines, such as the block move example, only the fact that dps is toggled in the proper sequence matters, not its actual value. in other words, the block move routine works the same whether dps is '0' or '1' on entry. observe that without the last instruction (inc auxr1), the routine will exit with dps in the opposite state.
25 at89c51rd2/ed2 4235d?8051?12/03 expanded ram (xram) the at89c51rd2/ed2 provides additional on-chip random access memory (ram) space for increased data parameter handling and high level language usage. at89c51rd2/ed2 device has expanded ram in external data space configurable up to 1792 bytes (see table 19). the at89c51rd2/ed2 internal data memory is mapped into four separate segments. the four segments are: 1. the lower 128 bytes of ram (addresses 00h to 7fh) are directly and indirectly addressable. 2. the upper 128 bytes of ram (addresses 80h to ffh) are indirectly addressable only. 3. the special function registers, sfrs, (addresses 80h to ffh) are directly addressable only. 4. the expanded ram bytes are indirectly accessed by movx instructions, and with the extram bit cleared in the auxr register (see table 19). the lower 128 bytes can be accessed by either direct or indirect addressing. the upper 128 bytes can be accessed by indirect addressing only. the upper 128 bytes occupy the same address space as the sfr. that means they have the same address, but are physically separate from sfr space. figure 8. internal and external data memory address when an instruction accesses an internal location above address 7fh, the cpu knows whether the access is to the upper 128 bytes of data ram or to sfr space by the addressing mode used in the instruction. instructions that use direct addressing access sfr space. for example: mov 0a0h, # data, accesses the sfr at location 0a0h (which is p2). instructions that use indirect addressing access the upper 128 bytes of data ram. for example: mov @r0, # data where r0 contains 0a0h, accesses the data byte at address 0a0h, rather than p2 (whose address is 0a0h). the xram bytes can be accessed by indirect addressing, with extram bit cleared and movx instructions. this part of memory which is physically located on-chip, logically occupies the first bytes of external data memory. the bits xrs0 and xrs1 are used to hide a part of the available xram as explained in table 19. this can be xram upper 128 bytes internal ram lower 128 bytes internal ram special function register 80h 80h 00 0ffh or 6ffh 0ffh 00 0ffh external data memory 0000 00ffh up to 06ffh 0ffffh indirect accesses direct accesses direct or indirect accesses 7fh
26 at89c51rd2/ed2 4235d?8051?12/03 useful if external peripherals are mapped at addresses already used by the internal xram. with extram = 0, the xram is indirectly addressed, using the movx instruction in combination with any of the registers r0, r1 of the selected bank or dptr. an access to xram will not affect ports p0, p2, p3.6 (wr) and p3.7 (rd). for example, with extram = 0, movx @r0, # data where r0 contains 0a0h, accesses the xram at address 0a0h rather than external memory. an access to external data memory locations higher than the accessible size of the xram will be performed with the movx dptr instructions in the same way as in the standard 80c51, with p0 and p2 as data/address busses, and p3.6 and p3.7 as write and read timing signals. accesses to xram above 0ffh can only be done by the use of dptr. with extram = 1 , movx @ri and movx @dptr will be similar to the standard 80c51.movx @ ri will provide an eight-bit address multiplexed with data on port0 and any output port pins can be used to output higher order address bits. this is to provide the external paging capability. movx @dptr will generate a sixteen-bit address. port2 outputs the high-order eight address bits (the contents of dph) while port0 multiplexes the low-order eight address bits (dpl) with data. movx @ ri and movx @dptr will generate either read or write signals on p3.6 (wr ) and p3.7 (rd ). the stack pointer (sp) may be located anywhere in the 256 bytes ram (lower and upper ram) internal data memory. the stack may not be located in the xram. the m0 bit allows to stretch the xram ti mings; if m0 is set, the read and write pulses are extended from 6 to 30 clock periods. this is useful to access external slow peripherals.
27 at89c51rd2/ed2 4235d?8051?12/03 registers table 19. auxr register auxr - auxiliary register (8eh) reset value = 0x00 10?hsb. xram?0b not bit addressable 76543210 dpu - m0 xrs2 xrs1 xrs0 extram ao bit number bit mnemonic description 7dpu disable weak pull-up cleared by software to activate the permanent weak pull-up (default) set by software to disable the w eak pull-up (reduce pow er consumption) 6- reserved the value read from this bit is indeterminate. do not set this bit. 5m0 pulse length cleared to stretch movx control: the rd and the wr pulse length is 6 clock periods (default). set to stretch movx control: the rd and the wr pulse length is 30 clock periods. 4xrs2 xram size xrs2 xrs1 xrs0 xram size 0 0 0 256 bytes 0 0 1 512 bytes 0 1 0 768 bytes(default) 0 1 1 1024 bytes 1 0 0 1792 bytes 3xrs1 2xrs0 1extram extram bit cleared to access internal xram using movx @ ri/ @ dptr. set to access external memory. programmed by hardware after power-up regarding hardware security byte (hsb), default setting, xram selected. 0ao ale output bit cleared, ale is emitted at a constant rate of 1/6 the oscillator frequency (or 1/3 if x2 mode is used). (default) set, ale is active only during a movx or movc instruction is used.
28 at89c51rd2/ed2 4235d?8051?12/03 reset introduction the reset sources are: power management, hardware watchdog, pca watchdog and reset input. figure 9. reset schematic reset input the reset input can be used to force a reset pulse longer than the internal reset con- trolled by the power monitor. rst input has a pull-down resistor allowing power-on reset by simply connecting an external capacitor to v cc as shown in figure 10. resistor value and input characteristics are discussed in the section ?dc characteristics? of the at89c51rd2/ed2 datasheet. figure 10. reset circuitry and power-on reset power monitor hardware watchdog pca watchdog rst internal reset rst r rst vss to internal reset rst vdd + b. power-on rese t a. rst input circuitry
29 at89c51rd2/ed2 4235d?8051?12/03 reset output as detailed in section ?hardware watchdog timer?, page 87, the wdt generates a 96- clock period pulse on the rst pin. in order to properly propagate this pulse to the rest of the application in case of external capacitor or power-supply supervisor circuit, a 1 k ? resistor must be added as shown figure 11. figure 11. recommended reset output schematic rst vdd + vss vdd rst 1k to other on-board circuitry at89c51xd2
30 at89c51rd2/ed2 4235d?8051?12/03 power monitor the por/pfd function monitors the internal power-supply of the cpu core memories and the peripherals, and if needed, suspends their activity when the internal power sup- ply falls below a safety threshold. this is achieved by applying an internal reset to them. by generating the reset the power monitor insures a correct start up when at89c51rd2/ed2 is powered up. description in order to startup and maintain the microcontroller in correct operating mode, v cc has to be stabilized in the v cc operating range and the oscillator has to be stabilized with a nominal amplitude compatible with logic level vih/vil. these parameters are controlled during the three phases: power-up, normal operation and power going down. see figure 12. figure 12. power monitor block diagram note: 1. once xtal1 high and low levels reach above and below vih/vil. a 1024 clock period delay will extend the reset coming from the power fail detect. if the power falls below the power fail detect threshold level, the reset will be applied immediately. the voltage regulator generates a regulated internal supply for the cpu core the mem- ories and the peripherals. spikes on the external vcc are smoothed by the voltage regulator. vcc power on reset power fail detect voltage regulator xtal1 (1) cpu core memories peripherals regulated supply rst pin hardware watchdog pca watchdog internal reset
31 at89c51rd2/ed2 4235d?8051?12/03 the power fail detect monitor the supply generated by the voltage regulator and gener- ate a reset if this supply falls below a safety threshold as illustrated in the figure 13 below. figure 13. power fail detect when the power is applied, the power monitor immediately asserts a reset. once the internal supply after the voltage regulator reach a safety level, the power monitor then looks at the xtal clock input. the internal reset will remain asserted until the xtal1 lev- els are above and below vih and vil. further more. an internal counter will count 1024 clock periods before the reset is de-asserted. if the internal power supply falls below a safety level, a reset is immediately asserted. . vcc t reset vcc
32 at89c51rd2/ed2 4235d?8051?12/03 timer 2 the timer 2 in the at89c51rd2/ed2 is the standard c52 timer 2. it is a 16-bit timer/counter: the count is maintained by two eight-bit timer registers, th2 and tl2 are cascaded. it is controlled by t2con (table 20) and t2mod (table 21) registers. timer 2 operation is similar to timer 0 and timer 1. c/t2 selects f osc /12 (timer operation) or external pin t2 (counter operation) as th e timer clock input. setting tr2 allows tl2 to increment by the selected input. timer 2 has 3 operating modes: capture, autoreload and baud rate generator. these modes are selected by the combination of rclk, tclk and cp/rl2 (t2con). refer to the atmel 8-bit microcontroller hardware manual for the description of capture and baud rate generator modes. timer 2 includes the following enhancements: auto-reload mode with up or down counter programmable clock-output auto-reload mode the auto-reload mode configures timer 2 as a 16-bit timer or event counter with auto- matic reload. if dcen bit in t2mod is cleared, timer 2 behaves as in 80c52 (refer to the atmel c51 microcontroller hardware manual). if dcen bit is set, timer 2 acts as an up/down timer/counter as shown in figure 14. in this mode the t2ex pin controls the direction of count. when t2ex is high, timer 2 counts up. timer overflow occurs at ffffh which sets the tf2 flag and generates an interrupt request. the overflow also causes the 16-bit value in rcap2h and rcap2l registers to be loaded into the timer registers th2 and tl2. when t2ex is low, timer 2 counts down. timer underflow occurs when the count in the timer registers th2 and tl2 equals the value stored in rcap2h and rcap2l registers. the underflow sets tf2 flag and reloads ffffh into the timer registers. the exf2 bit toggles when timer 2 overflows or underflows according to the direction of the count. exf2 does not generate any interrupt. this bit can be used to provide 17-bit resolution.
33 at89c51rd2/ed2 4235d?8051?12/03 figure 14. auto-reload mode up/down counter (dcen = 1) programmable clock-output in the clock-out mode, timer 2 operates as a 50% duty-cycle, programmable clock gen- erator (see figure 15). the input clock increments tl2 at frequency f clk periph /2. the timer repeatedly counts to overflow from a loaded value. at overflow, the contents of rcap2h and rcap2l registers are loaded into th2 and tl2. in this mode, timer 2 overflows do not generate interrupts. the formula gives the clock-out frequency as a function of the system oscillator frequency and the value in the rcap2h and rcap2l registers: for a 16 mhz system clock, timer 2 has a programmable frequency range of 61 hz (f clk periph /2 16 ) to 4 mhz (f clk periph /4). the generated clock signal is brought out to t2 pin (p1.0). timer 2 is programmed for the clock-out mode as follows: set t2oe bit in t2mod register. clear c/t2 bit in t2con register. determine the 16-bit reload value from the formula and enter it in rcap2h/rcap2l registers. enter a 16-bit initial value in timer registers th2/tl2. it can be the same as the reload value or a different one depending on the application. to start the timer, set tr2 run control bit in t2con register. it is possible to use timer 2 as a baud rate generator and a clock generator simulta- neously. for this configuration, the baud rates and clock frequencies are not independent since both functions use the values in the rcap2h and rcap2l registers. (down counting reload value) c/t2 tf2 tr2 t2 exf2 th2 (8-bit) tl2 (8-bit) rcap2h (8-bit) rcap2l ( 8-bit) ffh (8-bit) ffh (8-bit) toggle (up counting reload value) timer 2 interrup t f clk periph 0 1 t2con t2con t2con t2con t2ex: if dcen = 1, 1 = up if dcen = 1, 0 = down if dcen = 0, up countin g : 6 c lock o ? utfrequency f clkperiph 4 65536 rcap 2 h rcap 2 l ?) ? ( -------------------------------------------------------------------------------------------- - =
34 at89c51rd2/ed2 4235d?8051?12/03 figure 15. clock-out mode c/t2 = 0 :6 exf2 tr2 over- flow t2ex th 2 (8-bit) tl2 (8-bit) timer 2 rcap2h (8-bit) rcap2l (8-bit) t2oe t2 fclk periph t2con t2con t2con t2mod interrupt qd toggle exen2
35 at89c51rd2/ed2 4235d?8051?12/03 registers table 20. t2con register t2con - timer 2 control register (c8h) reset value = 0000 0000b bit addressable 76543210 tf2 exf2 rclk tclk exen2 tr2 c/t2# cp/rl2# bit number bit mnemonic description 7 tf2 timer 2 overflow flag must be cleared by software. set by hardware on timer 2 overflow, if rclk = 0 and tclk = 0. 6exf2 timer 2 external flag set when a capture or a reload is caused by a negative transition on t2ex pin if exen2 = 1. when set, causes the cpu to vector to timer 2 interrupt routine when timer 2 interrupt is enabled. must be cleared by software. exf2 doesn?t cause an interrupt in up/down counter mode (dcen = 1). 5 rclk receive clock bit cleared to use timer 1 overflow as receive clock for serial port in mode 1 or 3. set to use timer 2 overflow as receiv e clock for serial port in mode 1 or 3. 4tclk transmit clock bit cleared to use timer 1 overflow as transmi t clock for serial port in mode 1 or 3. set to use timer 2 overflow as transmit clock for serial port in mode 1 or 3. 3exen2 timer 2 external enable bit cleared to ignore events on t2ex pin for timer 2 operation. set to cause a capture or reload when a negative transition on t2ex pin is detected, if timer 2 is not used to clock the serial port. 2tr2 timer 2 run control bit cleared to turn off timer 2. set to turn on timer 2. 1c/t2# timer/counter 2 select bit cleared for timer operation (input from internal clock system: f clk periph ). set for counter operation (input from t2 input pin, falling edge trigger). must be 0 for clock out mode. 0 cp/rl2# timer 2 capture/reload bi t if rclk = 1 or tclk = 1, cp/rl2# is ignored and timer is forced to auto-reload on timer 2 overflow. cleared to auto-reload on timer 2 overflows or negative transitions on t2ex pin if exen2=1. set to capture on negative transitions on t2ex pin if exen2 = 1.
36 at89c51rd2/ed2 4235d?8051?12/03 table 21. t2mod register t2mod - timer 2 mode control register (c9h) reset value = xxxx xx00b not bit addressable 76543210 ------t2oedcen bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6- reserved the value read from this bit is indeterminate. do not set this bit. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4- reserved the value read from this bit is indeterminate. do not set this bit. 3- reserved the value read from this bit is indeterminate. do not set this bit. 2- reserved the value read from this bit is indeterminate. do not set this bit. 1t2oe timer 2 output enable bit cleared to program p1.0/t2 as clock input or i/o port. set to program p1.0/t2 as clock output. 0 dcen down counter enable bit cleared to disable timer 2 as up/down counter. set to enable timer 2 as up/down counter.
37 at89c51rd2/ed2 4235d?8051?12/03 programmable counter array (pca) the pca provides more timing capabilities with less cpu intervention than the standard timer/counters. its advantages include reduced software overhead and improved accu- racy. the pca consists of a dedicated timer/counter which serves as the time base for an array of five compare/capture modules. its clock input can be programmed to count any one of the following signals: peripheral clock frequency (f clk periph ) 6 peripheral clock frequency (f clk periph ) 2 timer 0 overflow external input on eci (p1.2) each compare/capture module can be programmed in any one of the following modes: rising and/or falling edge capture software timer high-speed output pulse width modulator module 4 can also be programmed as a watchdog timer (see section "pca watchdog timer", page 48). when the compare/capture modules are programmed in the capture mode, software timer, or high speed output mode, an interrupt can be generated when the module exe- cutes its function. all five modules plus the pca timer overflow share one interrupt vector. the pca timer/counter and compare/capture modules share port 1 for external i/o. these pins are listed below. if one or several bits in the port are not used for the pca, they can still be used for standard i/o. the pca timer is a common time base for all five modules (see figure 16). the timer count source is determined from the cps1 and cps0 bits in the cmod register (table 22) and can be programmed to run at: 1/6 the peripheral clock frequency (f clk periph ) 1/2 the peripheral clock frequency (f clk periph ) the timer 0 overflow the input on the eci pin (p1.2) pca component external i/o pin 16-bit counter p1.2/eci 16-bit module 0 p1.3/cex0 16-bit module 1 p1.4/cex1 16-bit module 2 p1.5/cex2 16-bit module 3 p1.6/cex3
38 at89c51rd2/ed2 4235d?8051?12/03 the cmod register includes three additi onal bits associated with the pca (see figure 16 and table 22). the cidl bit which allows the pca to stop during idle mode. the wdte bit which enables or disables the watchdog function on module 4. the ecf bit which when set causes an interrupt and the pca overflow flag cf (in the ccon sfr) to be set when the pca timer overflows. figure 16. pca timer/counter cidl cps1 cps0 ecf it ch cl 16 bit up counter to pca modules f clk periph /6 f clk periph /2 t0 ovf p1.2 idle cmod 0xd9 wdte cf cr ccon 0xd8 ccf4 ccf3 ccf2 ccf1 ccf0 overflow
39 at89c51rd2/ed2 4235d?8051?12/03 table 22. cmod register cmod - pca counter mode register (d9h) reset value = 00xx x000b not bit addressable the ccon register contains the run control bit for the pca and the flags for the pca timer (cf) and each module (refer to table 23). bit cr (ccon.6) must be set by software to run the pca. the pca is shut off by clearing this bit. bit cf: the cf bit (ccon.7) is set when the pca counter overflows and an interrupt will be generated if the ecf bit in the cmod register is set. the cf bit can only be cleared by software. bits 0 through 4 are the flags for the modules (bit 0 for module 0, bit 1 for module 1, etc.) and are set by hardware when either a match or a capture occurs. these flags also can only be cleared by software. 76543210 cidl wdte - - - cps1 cps0 ecf bit number bit mnemonic description 7cidl counter idle control cleared to program the pca counter to continue functioning during idle mode. set to program pca to be gated off during idle. 6wdte watchdog timer enable cleared to disable watchdog timer function on pca module 4. set to enable watchdog timer function on pca module 4. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4- reserved the value read from this bit is indeterminate. do not set this bit. 3- reserved the value read from this bit is indeterminate. do not set this bit. 2cps1 pca count pulse select cps1 cps0 selected pca input 0 0 internal clock f clk periph /6 0 1 internal clock f clk periph /2 1 0 timer 0 overflow 1 1 external clock at eci/p1.2 pin (max rate = f clk periph /4) 1cps0 0ecf pca enable counter overflow interrupt cleared to disable cf bit in ccon to inhibit an interrupt. set to enable cf bit in ccon to generate an interrupt.
40 at89c51rd2/ed2 4235d?8051?12/03 table 23. ccon register ccon - pca counter control register (d8h) reset value = 00x0 0000b not bit addressable the watchdog timer function is implemented in module 4 (see figure 19). the pca interrupt system is shown in figure 17. 76543210 cf cr - ccf4 ccf3 ccf2 ccf1 ccf0 bit number bit mnemonic description 7cf pca counter overflow flag set by hardware when the count er rolls over. cf flags an interrupt if bit ecf in cmod is set. cf may be set by either hardware or softw are but can only be cleared by software. 6cr pca counter run control bit must be cleared by software to turn the pca counter off. set by software to turn the pca counter on. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4 ccf4 pca module 4 interrupt flag must be cleared by software. set by hardware when a ma tch or capture occurs. 3 ccf3 pca module 3 interrupt flag must be cleared by software. set by hardware when a ma tch or capture occurs. 2 ccf2 pca module 2 interrupt flag must be cleared by software. set by hardware when a ma tch or capture occurs. 1 ccf1 pca module 1 interrupt flag must be cleared by software. set by hardware when a ma tch or capture occurs. 0 ccf0 pca module 0 interrupt flag must be cleared by software. set by hardware when a ma tch or capture occurs.
41 at89c51rd2/ed2 4235d?8051?12/03 figure 17. pca interrupt system pca modules: each one of the five compare/capture modules has six possible func- tions. it can perform: 16-bit capture, positive-edge triggered 16-bit capture, negative-edge triggered 16-bit capture, both positive and negative-edge triggered 16-bit software timer 16-bit high speed output 8-bit pulse width modulator in addition, module 4 can be used as a watchdog timer. each module in the pca has a special function register associated with it. these regis- ters are: ccapm0 for module 0, ccapm1 for module 1, etc. (see table 24). the registers contain the bits that control the mode that each module will operate in. the eccf bit (ccapmn.0 where n = 0, 1, 2, 3, or 4 depending on the module) enables the ccf flag in the ccon sfr to generate an interrupt when a match or compare occurs in the associated module. pwm (ccapmn.1) enables the pulse width modulation mode. the tog bit (ccapmn.2) when set causes the cex output associated with the module to toggle when there is a match between the pca counter and the modules capture/compare register. the match bit mat (ccapmn.3) when set will cause the ccfn bit in the ccon register to be set when there is a match between the pca counter and the modules capture/compare register. the next two bits capn (ccapmn.4) and capp (ccapmn.5) determine the edge that a capture input will be active on. the capn bit enables the negative edge, and the capp bit enables the positive edge. if both bits are set both edges will be enabled and a capture will occur for either transition. the last bit in the register ecom (ccapmn.6) when set enables the comparator function. cf cr ccon 0xd8 ccf4 ccf3 ccf2 ccf1 ccf0 module 4 module 3 module 2 module 1 module 0 ecf pca timer/counter eccfn ccapmn.0 cmod.0 ien0.6 ien0.7 to interrupt priority decoder ec ea
42 at89c51rd2/ed2 4235d?8051?12/03 table 24 shows the ccapmn settings for the various pca functions. table 24. ccapmn registers (n = 0-4) ccapm0 - pca module 0 compare/capture control register (0dah) ccapm1 - pca module 1 compare/capture control register (0dbh) ccapm2 - pca module 2 compare/capture control register (0dch) ccapm3 - pca module 3 compare/capture control register (0ddh) ccapm4 - pca module 4 compare/capture control register (0deh) reset value = x000 0000b not bit addressable 76543210 - ecomn cappn capnn matn togn pwmn eccfn bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6ecomn enable comparator cleared to disable the comparator function. set to enable the comparator function. 5 cappn capture positive cleared to disable positive edge capture. set to enable positive edge capture. 4capnn capture negative cleared to disable negative edge capture. set to enable negative edge capture. 3matn match when matn = 1, a match of the pca counter with this module's compare/capture register causes the ccfn bit in ccon to be set, flagging an interrupt. 2togn toggle when togn = 1, a match of the pca counter with this module's compare/capture register causes the cexn pin to toggle. 1pwmn pulse width modulation mode cleared to disable the cexn pin to be used as a pulse width modulated output. set to enable the cexn pin to be used as a pulse width modulated output. 0 ccf0 enable ccf interrupt cleared to disable compare/capture flag ccfn in the ccon register to generate an interrupt. set to enable compare/capture flag ccfn in the ccon register to generate an interrupt.
43 at89c51rd2/ed2 4235d?8051?12/03 table 25. pca module modes (ccapmn registers) there are two additional registers associated with each of the pca modules. they are ccapnh and ccapnl and these are the registers that store the 16-bit count when a capture occurs or a compare should occur. when a module is used in the pwm mode these registers are used to control the duty cycle of the output (see table 26 & table 27). table 26. ccapnh registers (n = 0 - 4) ccap0h - pca module 0 compare/capture control register high (0fah) ccap1h - pca module 1 compare/capture control register high (0fbh) ccap2h - pca module 2 compare/capture control register high (0fch) ccap3h - pca module 3 compare/capture control register high (0fdh) ccap4h - pca module 4 compare/capture control register high (0feh) reset value = 0000 0000b not bit addressable ecomn cappn capnn matn togn pwmm eccfn module function 0000000 no operation x10000x 16-bit capture by a positive-edge trigger on cexn x01000x 16-bit capture by a negative trigger on cexn x11000x 16-bit capture by a transition on cexn 100100x 16-bit software timer/compare mode. 100110x16-bit high s peed output 10000108-bit pwm 1001x0xwatc hdog timer (module 4 only) 76543210 -------- bit number bit mnemonic description 7 - 0 - pca module n compare/capture control ccapnh value
44 at89c51rd2/ed2 4235d?8051?12/03 table 27. ccapnl registers (n = 0 - 4) ccap0l - pca module 0 compare/capture control register low (0eah) ccap1l - pca module 1 compare/capture control register low (0ebh) ccap2l - pca module 2 compare/capture control register low (0ech) ccap3l - pca module 3 compare/capture control register low (0edh) ccap4l - pca module 4 compare/capture control register low (0eeh) reset value = 0000 0000b not bit addressable table 28. ch register ch - pca counter register high (0f9h) reset value = 0000 0000b not bit addressable table 29. cl register cl - pca counter register low (0e9h) reset value = 0000 0000b not bit addressable 76543210 -------- bit number bit mnemonic description 7 - 0 - pca module n compare/capture control ccapnl value 76543210 -------- bit number bit mnemonic description 7 - 0 - pca counter ch value 76543210 -------- bit number bit mnemonic description 7 - 0 - pca counter cl value
45 at89c51rd2/ed2 4235d?8051?12/03 pca capture mode to use one of the pca modules in the capture mode either one or both of the ccapm bits capn and capp for that module must be set. the external cex input for the mod- ule (on port 1) is sampled for a transition. when a valid transition occurs the pca hardware loads the value of the pca counter registers (ch and cl) into the module's capture registers (ccapnl and ccapnh). if the ccfn bit for the module in the ccon sfr and the eccfn bit in the ccapmn sfr are set then an interrupt will be generated (refer to figure 18). figure 18. pca capture mode 16-bit software timer/ compare mode the pca modules can be used as software timers by setting both the ecom and mat bits in the modules ccapmn register. the pca timer will be compared to the module's capture registers and when a ma tch occurs an interrupt will occur if the ccfn (ccon sfr) and the eccfn (ccapmn sfr) bits for the module are both set (see figure 19). cf cr ccon 0xd8 ch c l cc ap nh c ca pn l ccf4 ccf3 ccf2 ccf1 ccf0 pca it pca coun te r/timer ecomn ccapmn, n= 0 to 4 0xda to 0xde capnn matn togn pwmn eccfn cappn c ex.n capture
46 at89c51rd2/ed2 4235d?8051?12/03 figure 19. pca compare mode and pca watchdog timer before enabling ecom bit, ccapnl and ccapnh should be set with a non zero value, otherwise an unwanted match could happen. writing to ccapnh will set the ecom bit. once ecom is set, writing ccapnl will clear ecom so that an unwanted match doesn?t occur while modifying the compare value. writing to ccapnh will set ecom. for this reason, user software should write ccap nl first, and then ccapnh. of course, the ecom bit can still be controlled by accessing to ccapmn register. high speed output mode in this mode the cex output (on port 1) associated with the pca module will toggle each time a match occurs between the pca counter and the modules capture registers. to activate this mode the tog, mat, and ecom bits in the module's ccapmn sfr must be set (see figure 20). a prior write must be done to ccapnl and ccapnh before writing the ecomn bit. ch c l cc ap nh c ca pn l ecomn cc a pm n, n = 0 to 4 0xda to 0xde ca pnn ma tn togn pwmn e ccfn ca ppn 16 bit comparator ma tch cc on 0xd8 pca i t en ab le pca cou nte r/ time r reset * cidl cps1 cps0 ecf cm od 0xd9 wdte reset write to ccapnl wr ite t o ccapnh cf ccf2 ccf1 ccf0 cr ccf3 ccf4 10
47 at89c51rd2/ed2 4235d?8051?12/03 figure 20. pca high speed output mode before enabling ecom bit, ccapnl and ccapnh should be set with a non zero value, otherwise an unwanted match could happen. once ecom is set, writing ccapnl will clear ecom so that an unwanted match doesn?t occur while modifying the compare value. writing to ccapnh will set ecom. for this reason, user software should write ccap nl first, and then ccapnh. of course, the ecom bit can still be controlled by accessing to ccapmn register. pulse width modulator mode all of the pca modules can be used as pwm outputs. figure 21 shows the pwm func- tion. the frequency of the output depends on the source for the pca timer. all of the modules will have the same frequency of output because they all share the pca timer. the duty cycle of each module is independently variable using the modules capture reg- ister ccapln. when the value of the pca cl sfr is less than the value in the modules ccapln sfr the output will be low, when it is equal to or greater than the output will be high. when cl overflows from ff to 00, ccapln is reloaded with the value in ccaphn. this allows updating the pwm without glit ches. the pwm and ecom bits in the mod- ule's ccapmn register must be set to enable the pwm mode. ch cl ccapnh ccapnl ecomn cca pmn, n = 0 to 4 0xda to 0xde capnn matn togn p wmn eccfn cappn 1 6 b it comp ar ato r ma tch cf cr ccon 0xd8 ccf4 ccf3 ccf2 ccf1 ccf0 pca it enable cexn pca counter/timer write to ccapnh reset write to ccapnl 1 0
48 at89c51rd2/ed2 4235d?8051?12/03 figure 21. pca pwm mode pca watchdog timer an on-board watchdog timer is available with the pca to improve the reliability of the system without increasing chip count. watchdog timers are useful for systems that are susceptible to noise, power glitches, or electrostatic discharge. module 4 is the only pca module that can be programmed as a watchdog. however, this module can still be used for other modes if the watchdog is not needed. figure 19 shows a diagram of how the watchdog works. the user pre-loads a 16-bit value in the compare registers. just like the other compare modes, this 16-bit value is compared to the pca timer value. if a match is allowed to occur, an internal reset will be generated. this will not cause the rst pin to be driven high. in order to hold off the reset, the user has three options: 1. periodically change the compare value so it will never match the pca timer. 2. periodically change the pca timer value so it will never match the compare values. 3. disable the watchdog by clearing the wdte bit before a match occurs and then re-enable it. cl ccapnh ccapnl ecomn ccapmn, n= 0 to 4 0xda to 0xde capnn matn togn pwmn eccfn cappn 8-bit comparator cex n ?0? ?1? enable pca counter/timer overflow
49 at89c51rd2/ed2 4235d?8051?12/03 the first two options are more reliable because the watchdog timer is never disabled as in option #3. if the program counter ever goes astray, a match will eventually occur and cause an internal reset. the second option is also not recommended if other pca mod- ules are being used. remember, the pca timer is the time base for all modules; changing the time base for other modules would not be a good idea. thus, in most appli- cations the first solution is the best option. this watchdog timer won?t generate a reset out on the reset pin.
50 at89c51rd2/ed2 4235d?8051?12/03 serial i/o port the serial i/o port in the at89c51rd2/ed2 is compatible with the serial i/o port in the 80c52. it provides both synchronous and asynchronous communication modes. it operates as a universal asynchronous receiver and transmitter (uart) in three full-duplex modes (modes 1, 2 and 3). asynchronous transmission and reception can occur simultaneously and at different baud rates serial i/o port includes the following enhancements: framing error detection automatic address recognition framing error detection framing bit error detection is provided for the three asynchronous modes (modes 1, 2 and 3). to enable the framing bit error detection feature, set smod0 bit in pcon regis- ter (see figure 22). figure 22. framing error block diagram when this feature is enabled, the receiver checks each incoming data frame for a valid stop bit. an invalid stop bit may result from noise on the serial lines or from simultaneous transmission by two cpus. if a valid stop bit is not found, the framing error bit (fe) in scon register (see table 33.) bit is set. software may examine fe bit after each reception to check for data errors. once set, only software or a reset can clear fe bit. subsequently received frames with valid stop bits cannot clear fe bit. when fe feature is enabled, ri rises on stop bit instead of the last data bit (see figure 23. and figure 24.). figure 23. uart timings in mode 1 ri ti rb8 tb8 ren sm2 sm1 sm0/fe idl pd gf0 gf1 pof - smod0 smod1 to uart framing error control sm0 to uart mode control (smod0 = 0) set fe bit if stop bit is 0 (framing error) (smod0 = 1) scon (98h) pcon (87h) data byte ri smod0=x stop bit start bit rxd d7 d6 d5 d4 d3 d2 d1 d0 fe smod0=1
51 at89c51rd2/ed2 4235d?8051?12/03 figure 24. uart timings in modes 2 and 3 automatic address recognition the automatic address recognition feature is enabled when the multiprocessor commu- nication feature is enabled (sm2 bit in scon register is set). implemented in hardware, automatic address recognition enhances the multiprocessor communication feature by allowing the seri al port to examine the address of each incoming command frame. only when the serial port recognizes its own address, the receiver sets ri bit in scon register to generate an interrupt. this ensures that the cpu is not interrupted by command frames addressed to other devices. if desired, the user may enable the automatic address recognition feature in mode 1.in this configuration, the stop bit takes the place of the ninth data bit. bit ri is set only when the received command frame address matches the device?s address and is terminated by a valid stop bit. to support automatic address recognition, a device is identified by a given address and a broadcast address. note: the multiprocessor communication and automatic address recognition features cannot be enabled in mode 0 (i. e. setting sm2 bit in scon register in mode 0 has no effect). given address each device has an individual address that is specified in saddr register; the saden register is a mask byte that contains don?t-care bits (defined by zeros) to form the device?s given address. the don?t-care bits provide the flexibility to address one or more slaves at a time. the following example illustrates how a given address is formed. to address a device by its individual address, the saden mask byte must be 1111 1111b . for example: saddr0101 0110b saden 1111 1100b given0101 01xxb the following is an example of how to use given addresses to address different slaves: slave a:saddr1111 0001b saden 1111 1010b given1111 0x0xb slave b:saddr1111 0011b saden 1111 1001b given1111 0xx1b slave c:saddr1111 0010b saden 1111 1101b given1111 00x1b ri smod0=0 data byte ninth bit stop bit start bit rxd d8 d7 d6 d5 d4 d3 d2 d1 d0 ri smod0=1 fe smod0=1
52 at89c51rd2/ed2 4235d?8051?12/03 the saden byte is selected so that each slave may be addressed separately. for slave a, bit 0 (the lsb) is a don?t-care bit; for slaves b and c, bit 0 is a 1.to commu- nicate with slave a only, the master must send an address where bit 0 is clear (e. g. 1111 0000b ). for slave a, bit 1 is a 1; for slaves b and c, bit 1 is a don?t care bit. to communicate with slaves b and c, but not slave a, the master must send an address with bits 0 and 1 both set (e. g. 1111 0011b ). to communicate with slaves a, b and c, the master must send an address with bit 0 set, bit 1 clear, and bit 2 clear (e. g. 1111 0001b ). broadcast address a broadcast address is formed from the logical or of the saddr and saden registers with zeros defined as don?t-care bits, e. g. : saddr 0101 0110b saden 1111 1100b broadcast =saddr or saden1111 111xb the use of don?t-care bits provides flexibility in defining the broadcast address, however in most applications, a broadcast address is ffh. the following is an example of using broadcast addresses: slave a:saddr1111 0001b saden 1111 1010b broadcast1111 1x11b, slave b:saddr1111 0011b saden 1111 1001b broadcast1111 1x11b, slave c:saddr=1111 0011b saden 1111 1101b broadcast1111 1111b for slaves a and b, bit 2 is a don?t care bit; for slave c, bit 2 is set. to communicate with all of the slaves, the master must send an address ffh. to communicate with slaves a and b, but not slave c, the master can send and address fbh. reset addresses on reset, the saddr and saden registers are initialized to 00h, i. e. the given and broadcast addresses are xxxx xxxxb (all don?t-care bits). this ensures that the serial port will reply to any address, and so, that it is backwards compatible with the 80c51 microcontrollers that do not support automatic address recognition.
53 at89c51rd2/ed2 4235d?8051?12/03 registers table 30. saden register saden - slave address mask register (b9h) reset value = 0000 0000b not bit addressable table 31. saddr register saddr - slave address register (a9h) reset value = 0000 0000b not bit addressable baud rate selection for uart for mode 1 and 3 the baud rate generator for transmit and receive clocks can be selected separately via the t2con and bdrcon registers. figure 25. baud rate selection 76543210 76543210 rclk / 16 rbck int_brg 0 1 timer1 0 1 0 1 timer2 int_brg timer1 timer2 timer_brg_rx rx clock / 16 0 1 timer_brg_tx tx clock tbck tclk
54 at89c51rd2/ed2 4235d?8051?12/03 table 32. baud rate selection table uart internal baud rate generator (brg) when the internal baud rate generator is used, the baud rates are determined by the brg overflow depending on the brl reload value, the value of spd bit (speed mode) in bdrcon register and the value of the smod1 bit in pcon register. figure 26. internal baud rate the baud rate for uart is token by formula: tclk (t2con) rclk (t2con) tbck (bdrcon) rbck (bdrcon) clock source uart tx clock source uart rx 0000timer 1timer 1 1000timer 2timer 1 0100timer 1timer 2 1100timer 2timer 2 x 0 1 0 int_brg timer 1 x 1 1 0 int_brg timer 2 0 x 0 1 timer 1 int_brg 1 x 0 1 timer 2 int_brg x x 1 1 int_brg int_brg brg 0 1 /6 brl /2 0 1 int_brg spd brr smod1 auto reload counter overflow f per baud_rate = 6 (1-spd) ? 32 ? (256 -brl) 2 smod1 ? f per brl = 256 - 6 (1-spd) ? 32 ? baud_rate 2 smod1 ? f per
55 at89c51rd2/ed2 4235d?8051?12/03 table 33. scon register scon - serial control register (98h) reset value = 0000 0000b bit addressable 76543210 fe/sm0 sm1 sm2 ren tb8 rb8 ti ri bit number bit mnemonic description 7 fe framing error bit (smod0=1 ) clear to reset the error state, not cleared by a valid stop bit. set by hardware when an invalid stop bit is detected. smod0 must be set to enable access to the fe bit. sm0 serial port mode bit 0 refer to sm1 for serial port mode selection. smod0 must be cleared to enable access to the sm0 bit. 6sm1 serial port mode bit 1 sm0 sm1 mode baud rate 0 0 shift register f xtal /12 (or f xtal /6 in mode x2) 0 1 8-bit uartvariable 1 0 9-bit uartf xtal /64 or f xtal /32 1 1 9-bit uartvariable 5sm2 serial port mode 2 bit / multiprocessor communication enable bit clear to disable multiprocessor communication feature. set to enable multiprocessor communication feature in mode 2 and 3, and eventually mode 1.this bit should be cleared in mode 0. 4ren reception enable bit clear to disable serial reception. set to enable serial reception. 3tb8 transmitter bit 8 / ninth bit to transmit in modes 2 and 3 clear to transmit a logic 0 in the 9th bit. set to transmit a logic 1 in the 9th bit. 2rb8 receiver bit 8 / ninth bit received in modes 2 and 3 cleared by hardware if 9th bit received is a logic 0. set by hardware if 9th bit received is a logic 1. in mode 1, if sm2 = 0, rb8 is the received stop bit. in mode 0 rb8 is not used. 1ti transmit interrupt flag clear to acknowledge interrupt. set by hardware at the end of the 8th bit time in mode 0 or at the beginning of the stop bit in the other modes. 0ri receive interrupt flag clear to acknowledge interrupt. set by hardware at the end of the 8th bit time in mode 0, see figure 23. and figure 24. in the other modes.
56 at89c51rd2/ed2 4235d?8051?12/03 table 34. example of computed value when x2=1, smod1=1, spd=1 table 35. example of computed value when x2=0, smod1=0, spd=0 the baud rate generator can be used for mode 1 or 3 (refer to figure 25.), but also for mode 0 for uart, thanks to the bit src located in bdrcon register (table 42.) uart registers table 36. saden register saden - slave address mask register for uart (b9h) reset value = 0000 0000b table 37. saddr register saddr - slave address register for uart (a9h) reset value = 0000 0000b baud rates f osc = 16. 384 mhz f osc = 24mhz brl error (%) brl error (%) 115200 247 1.23 243 0.16 57600 238 1.23 230 0.16 38400 229 1.23 217 0.16 28800 220 1.23 204 0.16 19200 203 0.63 178 0.16 9600 149 0.31 100 0.16 4800 43 1.23 - - baud rates f osc = 16. 384 mhz f osc = 24mhz brl error (%) brl error (%) 4800 247 1.23 243 0.16 2400 238 1.23 230 0.16 1200 220 1.23 202 3.55 600 185 0.16 152 0.16 76543210 76543210
57 at89c51rd2/ed2 4235d?8051?12/03 table 38. sbuf register sbuf - serial buffer register for uart (99h) reset value = xxxx xxxxb table 39. brl register brl - baud rate reload register for the internal baud rate generator, uart (9ah) reset value = 0000 0000b 76543210 76543210
58 at89c51rd2/ed2 4235d?8051?12/03 table 40. t2con register t2con - timer 2 control register (c8h) reset value = 0000 0000b bit addressable 76543210 tf2 exf2 rclk tclk exen2 tr2 c/t2# cp/rl2# bit number bit mnemonic description 7tf2 timer 2 overflow flag must be cleared by software. set by hardware on timer 2 overflow, if rclk = 0 and tclk = 0. 6exf2 timer 2 external flag set when a capture or a reload is caused by a negative transition on t2ex pin if exen2=1. when set, causes the cpu to vector to timer 2 interrupt routine when timer 2 interrupt is enabled. must be cleared by software. exf2 doesn?t cause an interrupt in up/down counter mode (dcen = 1) 5 rclk receive clock bit for uart cleared to use timer 1 overflow as receive clock for serial port in mode 1 or 3. set to use timer 2 overflow as receive clock for serial port in mode 1 or 3. 4tclk transmit clock bit for uart cleared to use timer 1 overflow as transmit clock for serial port in mode 1 or 3. set to use timer 2 overflow as transmit clock for serial port in mode 1 or 3. 3exen2 timer 2 external enable bit cleared to ignore events on t2ex pin for timer 2 operation. set to cause a capture or reload when a negative transition on t2ex pin is detected, if timer 2 is not used to clock the serial port. 2tr2 timer 2 run control bit cleared to turn off timer 2. set to turn on timer 2. 1c/t2# timer/counter 2 select bit cleared for timer operation (input fr om internal clock system: f clk periph ). set for counter operation (input from t2 input pin, falling edge trigger). must be 0 for clock out mode. 0 cp/rl2# timer 2 capture/reload bit if rclk=1 or tclk=1, cp/rl2# is ignored and timer is forced to auto-reload on timer 2 overflow. cleared to auto-reload on timer 2 overflows or negative transitions on t2ex pin if exen2=1. set to capture on negative transitions on t2ex pin if exen2=1.
59 at89c51rd2/ed2 4235d?8051?12/03 table 41. pcon register pcon - power control register (87h) reset value = 00x1 0000b not bit addressable power-off flag reset value will be 1 only after a power on (cold reset). a warm reset doesn?t affect the value of this bit. 76543210 smod1 smod0 - pof gf1 gf0 pd idl bit number bit mnemonic description 7smod1 serial port mode bit 1 for uart set to select double baud rate in mode 1, 2 or 3. 6smod0 serial port mode bit 0 for uart cleared to select sm0 bit in scon register. set to select fe bit in scon register. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4pof power-off flag cleared to recognize next reset type. set by hardware when vcc rises from 0 to its nominal voltage. can also be set by software. 3gf1 general purpose flag cleared by user for general purpose usage. set by user for general purpose usage. 2gf0 general purpose flag cleared by user for general purpose usage. set by user for general purpose usage. 1pd power-down mode bit cleared by hardware when reset occurs. set to enter power-down mode. 0idl idle mode bit cleared by hardware when interrupt or reset occurs. set to enter idle mode.
60 at89c51rd2/ed2 4235d?8051?12/03 table 42. bdrcon register bdrcon - baud rate control register (9bh) reset value = xxx0 0000b not bit addressable 76543210 - - - brr tbck rbck spd src bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit 6- reserved the value read from this bit is indeterminate. do not set this bit 5- reserved the value read from this bit is indeterminate. do not set this bit. 4brr baud rate run control bit cleared to stop the internal baud rate generator. set to start the internal baud rate generator. 3tbck transmission baud rate generator selection bit for uart cleared to select timer 1 or timer 2 for the baud rate generator. set to select internal baud rate generator. 2rbck reception baud rate generator selection bit for uart cleared to select timer 1 or timer 2 for the baud rate generator. set to select internal baud rate generator. 1 spd baud rate speed control bit for uart cleared to select the slow baud rate generator. set to select the fast baud rate generator. 0src baud rate source select bit in mode 0 for uart cleared to select f osc /12 as the baud rate generator (f clk periph /6 in x2 mode). set to select the internal baud rate generator for uarts in mode 0.
61 at89c51rd2/ed2 4235d?8051?12/03 keyboard interface the at89c51rd2/ed2 implements a keyboard interface allowing the connection of a 8 x n matrix keyboard. it is based on 8 inputs with programmable interrupt capability on both high or low level. these inputs are available as alternate function of p1 and allow to exit from idle and power-down modes. the keyboard interfaces with the c51 core through 3 special function registers: kbls, the keyboard level selection register (t able 45), kbe, the keyboard interrupt enable register (table 44), and kbf, the keyboard flag register (table 43). interrupt the keyboard inputs are considered as 8 independent interrupt sources sharing the same interrupt vector. an interrupt enable bit (kbd in ie1) allows global enable or dis- able of the keyboard interrupt (see figure 27). as detailed in figure 28 each keyboard input has the capability to detect a programmable level according to kbls. x bit value. level detection is then reported in interrupt flags kbf.x that can be masked by software using kbe. x bits. this structure allow keyboard arrangement from 1 by n to 8 by n matrix and allows usage of p1 inputs for other purpose. figure 27. keyboard interface block diagram figure 28. keyboard input circuitry power reduction mode p1 inputs allow exit from idle and power-down modes as detailed in section ?power management?, page 83. p 1:x kbe.x kbf.x kbls.x 0 1 vcc internal pullup p1.0 keyboard interfac e interrupt request kbd ie1 input circuitry p1.1 input circuitry p1.2 input circuitry p1.3 input circuitry p1.4 input circuitry p1.5 input circuitry p1.6 input circuitry p1.7 input circuitry kbdit
62 at89c51rd2/ed2 4235d?8051?12/03 registers table 43. kbf register kbf - keyboard flag register (9eh) reset value = 0000 0000b this register is read only access, all flags are automatically cleared by reading the register. 76543210 kbf7 kbf6 kbf5 kbf4 kbf3 kbf2 kbf1 kbf0 bit number bit mnemonic description 7kbf7 keyboard line 7 flag set by hardware when the port line 7 det ects a programmed level. it generates a keyboard interrupt request if the kbkbie.7 bit in kbie register is set. must be cleared by software. 6kbf6 keyboard line 6 flag set by hardware when the port line 6 det ects a programmed level. it generates a keyboard interrupt request if the kbie.6 bit in kbie register is set. must be cleared by software. 5kbf5 keyboard line 5 flag set by hardware when the port line 5 det ects a programmed level. it generates a keyboard interrupt request if the kbie.5 bit in kbie register is set. must be cleared by software. 4kbf4 keyboard line 4 flag set by hardware when the port line 4 det ects a programmed level. it generates a keyboard interrupt request if the kbie.4 bit in kbie register is set. must be cleared by software. 3kbf3 keyboard line 3 flag set by hardware when the port line 3 det ects a programmed level. it generates a keyboard interrupt request if the kbie.3 bit in kbie register is set. must be cleared by software. 2kbf2 keyboard line 2 flag set by hardware when the port line 2 det ects a programmed level. it generates a keyboard interrupt request if the kbie.2 bit in kbie register is set. must be cleared by software. 1kbf1 keyboard line 1 flag set by hardware when the port line 1 det ects a programmed level. it generates a keyboard interrupt request if the kbie.1 bit in kbie register is set. must be cleared by software. 0kbf0 keyboard line 0 flag set by hardware when the port line 0 det ects a programmed level. it generates a keyboard interrupt request if the kbie.0 bit in kbie register is set. must be cleared by software.
63 at89c51rd2/ed2 4235d?8051?12/03 table 44. kbe register kbe-keyboard input enable register (9dh) reset value = 0000 0000b 76543210 kbe7 kbe6 kbe5 kbe4 kbe3 kbe2 kbe1 kbe0 bit number bit mnemonic description 7kbe7 keyboard line 7 enable bit cleared to enable standard i/o pin. set to enable kbf.7 bit in kbf register to generate an interrupt request. 6kbe6 keyboard line 6 enable bit cleared to enable standard i/o pin. set to enable kbf.6 bit in kbf register to generate an interrupt request. 5kbe5 keyboard line 5 enable bit cleared to enable standard i/o pin. set to enable kbf.5 bit in kbf register to generate an interrupt request. 4kbe4 keyboard line 4 enable bit cleared to enable standard i/o pin. set to enable kbf.4 bit in kbf register to generate an interrupt request. 3kbe3 keyboard line 3 enable bit cleared to enable standard i/o pin. set to enable kbf.3 bit in kbf register to generate an interrupt request. 2kbe2 keyboard line 2 enable bit cleared to enable standard i/o pin. set to enable kbf.2 bit in kbf register to generate an interrupt request. 1kbe1 keyboard line 1 enable bit cleared to enable standard i/o pin. set to enable kbf.1 bit in kbf register to generate an interrupt request. 0kbe0 keyboard line 0 enable bit cleared to enable standard i/o pin. set to enable kbf.0 bit in kbf register to generate an interrupt request.
64 at89c51rd2/ed2 4235d?8051?12/03 table 45. kbls register kbls-keyboard level selector register (9ch) reset value = 0000 0000b 76543210 kbls7 kbls6 kbls5 kbls4 kbls3 kbls2 kbls1 kbls0 bit number bit mnemonic description 7kbls7 keyboard line 7 level selection bit cleared to enable a low level detection on port line 7. set to enable a high level detection on port line 7. 6kbls6 keyboard line 6 level selection bit cleared to enable a low level detection on port line 6. set to enable a high level detection on port line 6. 5kbls5 keyboard line 5 level selection bit cleared to enable a low level detection on port line 5. set to enable a high level detection on port line 5. 4kbls4 keyboard line 4 level selection bit cleared to enable a low level detection on port line 4. set to enable a high level detection on port line 4. 3kbls3 keyboard line 3 level selection bit cleared to enable a low level detection on port line 3. set to enable a high level detection on port line 3. 2kbls2 keyboard line 2 level selection bit cleared to enable a low level detection on port line 2. set to enable a high level detection on port line 2. 1kbls1 keyboard line 1 level selection bit cleared to enable a low level detection on port line 1. set to enable a high level detection on port line 1. 0kbls0 keyboard line 0 level selection bit cleared to enable a low level detection on port line 0. set to enable a high level detection on port line 0.
65 at89c51rd2/ed2 4235d?8051?12/03 serial port interface (spi) the serial peripheral interface module (spi) allows full-duplex, synchronous, serial communication between the mcu and peripheral devices, including other mcus. features features of the spi module include the following: full-duplex, three-wire synchronous transfers master or slave operation eight programmable master clock rates serial clock with programmable polarity and phase master mode fault error flag with mcu interrupt capability write collision flag protection signal description figure 29 shows a typical spi bus configuration using one master controller and many slave peripherals. the bus is made of three wires connecting all the devices. figure 29. spi master/slaves interconnection the master device selects the individual slave devices by using four pins of a parallel port to control the four ss pins of the slave devices. master output slave input (mosi) this 1-bit signal is directly connected betw een the master device and a slave device. the mosi line is used to transfer data in series from the master to the slave. therefore, it is an output signal from the master, and an input signal to a slave. a byte (8-bit word) is transmitted most significant bit (msb) first, least significant bit (lsb) last. master input slave output (miso) this 1-bit signal is directly connected betw een the slave device and a master device. the miso line is used to transfer data in series from the slave to the master. therefore, it is an output signal from the slave, and an input signal to the master. a byte (8-bit word) is transmitted most significant bit (msb) first, least significant bit (lsb) last. spi serial clock (sck) this signal is used to synchronize the data movement both in and out of the devices through their mosi and miso lines. it is driven by the master for eight clock cycles which allows to exchange one byte on the serial lines. slave select (ss ) each slave peripheral is selected by one slave select pin (ss ). this signal must stay low for any message for a slave. it is obvious that only one master (ss high level) can slave 1 miso mosi sck ss miso mosi sck ss port 0 1 2 3 slave 3 miso mosi sck ss slave 4 miso mosi sck ss slave 2 miso mosi sck ss vdd master
66 at89c51rd2/ed2 4235d?8051?12/03 drive the network. the master may select each slave device by software through port pins (figure 30). to prevent bus conflicts on the miso line, only one slave should be selected at a time by the master for a transmission. in a master configuration, the ss line can be used in conjunction with the modf flag in the spi status register (spsta) to prevent multiple masters from driving mosi and sck (see error conditions). a high level on the ss pin puts the miso line of a slave spi in a high-impedance state. the ss pin could be used as a general-purpose if the following conditions are met: the device is configured as a master and the ssdis control bit in spcon is set. this kind of configuration can be found when only one master is driving the network and there is no way that the ss pin could be pulled low. therefore, the modf flag in the spsta will never be set (1) . the device is configured as a slave with cpha and ssdis control bits set (2) . this kind of configuration can happen when the system comprises one master and one slave only. therefore, the device should always be selected and there is no reason that the master uses the ss pin to select the communicating slave device. note: 1. clearing ssdis control bit does not clear modf. 2. special care should be taken not to set ssdis control bit when cpha = ?0? because in this mode, the ss is used to start the transmission. baud rate in master mode, the baud rate can be selected from a baud rate generator which is con- trolled by three bits in the spcon register: spr2, spr1 and spr0.the master clock is selected from one of seven clock rates resulting from the division of the internal clock by 2, 4, 8, 16, 32, 64 or 128. table 46 gives the different clock rates selected by spr2:spr1:spr0. table 46. spi master baud rate selection spr2 spr1 spr0 clock rate baud rate divisor (bd) 000 f clk periph /2 2 001 f clk periph /4 4 010 f clk periph /8 8 011 f clk periph /16 16 100 f clk periph /32 32 101 f clk periph /64 64 110 f clk periph /128 128 1 1 1 don?t use no brg
67 at89c51rd2/ed2 4235d?8051?12/03 functional description figure 30 shows a detailed structure of the spi module. figure 30. spi module block diagram operating modes the serial peripheral interface can be configured in one of the two modes: master mode or slave mode. the configuration and initia lization of the spi module is made through one register: the serial peripheral control register (spcon) once the spi is configured, the data exchange is made using: spcon the serial peripheral status register (spsta) the serial peripheral data register (spdat) during an spi transmission, data is simultaneously transmitted (shifted out serially) and received (shifted in serially). a serial clock line (sck) synchronizes shifting and sam- pling on the two serial data lines (mosi and miso). a slave select line (ss ) allows individual selection of a slave spi device; slave devices that are not selected do not interfere with spi bus activities. when the master device transmits data to the slave device via the mosi line, the slave device responds by sending data to the master device via the miso line. this implies full-duplex transmission with both data out and data in synchronized with the same clock (figure 31). shift register 0 1 2 3 4 5 6 7 internal bus pin control logic miso mosi sck m s clock logic clock divider clock select /4 /64 /128 spi interrupt request 8-bit bus 1-bit signa l ss fclk periph /32 /8 /16 receive data register spdat spi control spsta cpha spr0 spr1 cpol mstr ssdis spen spr2 spcon wcol modf spif -----
68 at89c51rd2/ed2 4235d?8051?12/03 figure 31. full-duplex master-slave interconnection master mode the spi operates in master mode when the master bit, mstr (1) , in the spcon register is set. only one master spi device can initiate transmissions. software begins the trans- mission from a master spi module by writing to the serial peripheral data register (spdat). if the shift register is empty, the byte is immediately transferred to the shift register. the byte begins shifting out on mosi pin under the control of the serial clock, sck. simultaneously, another byte shifts in from the slave on the master?s miso pin. the transmission ends when the serial peripheral transfer data flag, spif, in spsta becomes set. at the same time that spif becomes set, the received byte from the slave is transferred to the receive data register in spdat. software clears spif by reading the serial peripheral status register (spsta) with the spif bit set, and then reading the spdat. slave mode the spi operates in slave mode when the master bit, mstr (2) , in the spcon register is cleared. before a data transmission occurs, the slave select pin, ss , of the slave device must be set to ?0?. ss must remain low until the transmission is complete. in a slave spi module, data enters the shift register under the control of the sck from the master spi module. after a byte enters the shift register, it is immediately trans- ferred to the receive data register in spdat, and the spif bit is set. to prevent an overflow condition, slave software must then read the spdat before another byte enters the shift register (3) . a slave spi must complete the write to the spdat (shift reg- ister) at least one bus cycle before the master spi starts a transmission. if the write to the data register is late, the spi transmits the data already in the shift register from the previous transmission. the maximum sck frequency allowed in slave mode is f clk periph /4. transmission formats software can select any of four combinations of serial clock (sck) phase and polarity using two bits in the spcon: the clock polarity (cpol (4) ) and the clock phase (cpha 4 ). cpol defines the default sck line level in idle state. it has no significant effect on the transmission format. cpha defines the edges on which the input data are sampled and the edges on which the output data are shifted (figure 32 and figure 33). the clock phase and polarity should be identical for the master spi device and the com- municating slave device. 8-bit shift register spi clock generator master mcu 8-bit shift register miso miso mosi mosi sck sck vss vdd ss ss slave mcu 1. the spi module should be configured as a master before it is enabled (spen set). also, the master spi should be configured before the slave spi. 2. the spi module should be configured as a slave before it is enabled (spen set). 3. the maximum frequency of the sck for an spi configured as a slave is the bus clock speed. 4. before writing to the cpol and cpha bits, the spi should be disabled (spen = ?0?).
69 at89c51rd2/ed2 4235d?8051?12/03 figure 32. data transmission format (cpha = 0) figure 33. data transmission format (cpha = 1) figure 34. cpha/ss timing as shown in figure 32, the first sck edge is the msb capture strobe. therefore, the slave must begin driving its data before the first sck edge, and a falling edge on the ss pin is used to start the transmission. the ss pin must be toggled high and then low between each byte transmitted (figure 34). figure 33 shows an spi transmission in which cpha is ?1?. in this case, the master begins driving its mosi pin on the first sck edge. therefore, the slave uses the first sck edge as a start transmission signal. the ss pin can remain low between transmis- sions (figure 34). this format may be preferred in systems having only one master and only one slave driving the miso data line. msb bit6 bit5 bit4 bit3 bit2 bit1 lsb bit6 bit5 bit4 bit3 bit2 bit1 msb lsb 13 245678 capture point ss (to slave) miso (from slave) mosi (from master) sck (cpol = 1) sck (cpol = 0) spen (internal) sck cycle number msb bit6 bit5 bit4 bit3 bit2 bit1 lsb bit6 bit5 bit4 bit3 bit2 bit1 msb lsb 13 2 45678 capture point ss (to slave) miso (from slave) mosi (from master) sck (cpol = 1) sck (cpol = 0) spen (internal) sck cycle number byte 1 byte 2 byte 3 miso/mosi master ss slave ss (cpha = 1) slave ss (cpha = 0)
70 at89c51rd2/ed2 4235d?8051?12/03 error conditions the following flags in the spsta signal spi error conditions: mode fault (modf) mode fault error in master mode spi indicate s that the level on the slave select (ss ) pin is inconsistent with the actual mode of the device. modf is set to warn that there may be a multi-master conflict for system control. in this case, the spi system is affected in the following ways: an spi receiver/error cpu interrupt request is generated the spen bit in spcon is cleared. this disables the spi the mstr bit in spcon is cleared when ss disable (ssdis) bit in the spcon register is cleared, the modf flag is set when the ss signal becomes ?0?. however, as stated before, for a system with one master, if the ss pin of the master device is pulled low, there is no way that another master attempts to drive the network. in this case, to prevent the modf flag from being set, software can set the ssdis bit in the spcon register and therefore making the ss pin as a general-purpose i/o pin. clearing the modf bit is accomplished by a read of spsta register with modf bit set, followed by a write to the spcon register. spen control bit may be restored to its orig- inal set state after the modf bit has been cleared. write collision (wcol) a write collision (wcol) flag in the spsta is set when a write to the spdat register is done during a transmit sequence. wcol does not cause an interruption, and the transfer continues uninterrupted. clearing the wcol bit is done through a software sequence of an access to spsta and an access to spdat. overrun condition an overrun condition occurs when the master device tries to send several data bytes and the slave devise has not cleared the spif bit issuing from the previous data byte transmitted. in this case, the receiver buffer contains the byte sent after the spif bit was last cleared. a read of the spdat returns this byte. all others bytes are lost. this condition is not detected by the spi peripheral. ss error flag (sserr) a synchronous serial slave error occurs when ss goes high before the end of a received data in slave mode. sserr does not cause in interruption, this bit is cleared by writing 0 to spen bit (reset of the spi state machine). interrupts two spi status flags can generate a cpu interrupt requests: table 47. spi interrupts serial peripheral data transfer flag, spif: this bit is set by hardware when a transfer has been completed. spif bit generates transmitter cpu interrupt requests. mode fault flag, modf: this bit becomes set to indicate that the level on the ss is inconsistent with the mode of the spi. modf with ssdis reset, generates receiver/error cpu interrupt requests. when ssdis is set, no modf interrupt request is generated. figure 35 gives a logical view of the above statements. flag request spif (sp data transfer) spi transmitter interrupt request modf (mode fault) spi receiver/error interrupt request (if ssdis = ?0?)
71 at89c51rd2/ed2 4235d?8051?12/03 figure 35. spi interrupt requests generation registers there are three registers in the module that provide c ontrol, status and data storage functions. these registers are describes in the following paragraphs. serial peripheral control register (spcon) the serial peripheral control register does the following: selects one of the master clock rates configure the spi module as master or slave selects serial clock polarity and phase enables the spi module frees the ss pin for a general-purpose table 48 describes this register and explains the use of each bit table 48. spcon register spcon - serial peripheral control register (0c3h) ssdis modf cpu interrupt request spi receiver/error cpu interrupt request spi transmitter spi cpu interrupt request spif 76543210 spr2 spen ssdis mstr cpol cpha spr1 spr0 bit number bit mnemonic description 7 spr2 serial peripheral rate 2 bit with spr1 and spr0 define the clock rate. 6spen serial peripheral enable cleared to disable the spi interface. set to enable the spi interface. 5 ssdis ss disable cleared to enable ss in both master and slave modes. set to disable ss in both master and slave modes. in slave mode, this bit has no effect if cpha =?0?. when ssdis is set, no modf interrupt request is generated . 4mstr serial peripheral master cleared to configure the spi as a slave. set to configure the spi as a master. 3cpol clock polarity cleared to have the sck set to ?0? in idle state. set to have the sck set to ?1? in idle low. 2cpha clock phase cleared to have the data sampled when the sck leaves the idle state (see cpol). set to have the data sampled when the sck returns to idle state (see cpol).
72 at89c51rd2/ed2 4235d?8051?12/03 reset value = 0001 0100b not bit addressable serial peripheral status register (spsta) the serial peripheral status register contains flags to signal the following conditions: data transfer complete write collision inconsistent logic level on ss pin (mode fault error) table 49 describes the spsta register and explains the use of every bit in the register. table 49. spsta register spsta - serial peripheral status and control register (0c4h) 1 spr1 spr2 spr1 spr0 serial peripheral rate 00 0f clk periph /2 00 1 f clk periph /4 01 0 f clk periph /8 01 1f clk periph /16 10 0f clk periph /32 10 1f clk periph /64 11 0f clk periph /128 1 1 1 invalid 0 spr0 bit number bit mnemonic description 76543210 spifwcolsserrmodf---- bit number bit mnemonic description 7spif serial peripheral data transfer flag cleared by hardware to indicate data transfer is in progress or has been approved by a clearing sequence. set by hardware to indicate that the data transfer has been completed. 6wcol write collision flag cleared by hardware to indicate that no collision has occurred or has been approved by a clearing sequence. set by hardware to indicate that a collision has been detected. 5sserr synchronous serial slave error flag set by hardware when ss is de-asserted before the end of a received data. cleared by disabling the spi (clearing spen bit in spcon). 4modf mode fault cleared by hardware to indicate that the ss pin is at appropriate logic level, or has been approved by a clearing sequence. set by hardware to indicate that the ss pin is at inappropriate logic level. 3- reserved the value read from this bit is indeterminate. do not set this bit 2- reserved the value read from this bit is indeterminate. do not set this bit.
73 at89c51rd2/ed2 4235d?8051?12/03 reset value = 00x0 xxxxb not bit addressable serial peripheral data register (spdat) the serial peripheral data register (table 50) is a read/write buffer for the receive data register. a write to spdat places data directly into the shift register. no transmit buffer is available in this model. a read of the spdat returns the value located in the receive buffer and not the content of the shift register. table 50. spdat register spdat - serial peripheral data register (0c5h) reset value = indeterminate r7:r0: receive data bits spcon, spsta and spdat registers may be read and written at any time while there is no on-going exchange. however, special care should be taken when writing to them while a transmission is on-going: do not change spr2, spr1 and spr0 do not change cpha and cpol do not change mstr clearing spen would immediately disable the peripheral writing to the spdat will cause an overflow. 1- reserved the value read from this bit is indeterminate. do not set this bit. 0- reserved the value read from this bit is indeterminate. do not set this bit. bit number bit mnemonic description 76543210 r7 r6 r5 r4 r3 r2 r1 r0
74 at89c51rd2/ed2 4235d?8051?12/03 interrupt system the at89c51rd2/ed2 has a total of 9 interrupt vectors: two external interrupts (int0 and int1 ), three timer interrupts (timers 0, 1 and 2), the serial port interrupt, spi inter- rupt, keyboard interrupt and the pca global interrupt. these interrupts are shown in figure 36. figure 36. interrupt control system each of the interrupt sources can be individually enabled or disabled by setting or clear- ing a bit in the interrupt enable register (table 54 and table 56). this register also contains a global disable bit, which must be cleared to disable all interrupts at once. each interrupt source can also be individually programmed to one out of four priority lev- els by setting or clearing a bit in the interrupt priority register (table 57) and in the interrupt priority high register (table 55 and table 56) shows the bit values and priority levels associated with each combination. ie1 0 3 high priority interrupt interrupt polling sequence, decreasing from high to low priority low priority interrupt global disable individual enable exf2 tf2 ti ri tf0 int0 int1 tf1 iph, ipl ie0 0 3 0 3 0 3 0 3 0 3 0 3 pca it kbd it spi it 0 3 0 3
75 at89c51rd2/ed2 4235d?8051?12/03 registers the pca interrupt vector is located at address 0033h, the spi interrupt vector is located at address 004bh and keyboard interrupt vector is located at address 003bh. all other vectors addresses are the same as standard c52 devices. table 51. priority level bit values a low-priority interrupt can be interrupted by a high priority interrupt, but not by another low-priority interrupt. a high-priority interrupt can?t be interrupted by any other interrupt source. if two interrupt requests of different priority levels are received simultaneously, the request of higher priority level is serviced. if interrupt requests of the same priority level are received simultaneously, an internal polling sequence determines which request is serviced. thus within each priority level there is a second priority structure determined by the polling sequence. iph.x ipl.x interrupt level priority 0 0 0 (lowest) 011 102 1 1 3 (highest)
76 at89c51rd2/ed2 4235d?8051?12/03 interrupt sources and vector addresses table 52. interrupt sources and vector addresses number polling priority interrupt source interrupt request vector address 0 0 reset 0000h 1 1 int0 ie0 0003h 2 2 timer 0 tf0 000bh 3 3 int1 ie1 0013h 4 4 timer 1 if1 001bh 5 6 uart ri+ti 0023h 6 7 timer 2 tf2+exf2 002bh 7 5 pca cf + ccfn (n = 0 - 4) 0033h 8 8 keyboard kbdit 003bh 9 9 - - 0043h 10 10 spi spiit 004bh
77 at89c51rd2/ed2 4235d?8051?12/03 table 53. ieno register ien0 - interrupt enable register (a8h) reset value = 0000 0000b bit addressable 76543210 ea ec et2 es et1 ex1 et0 ex0 bit number bit mnemonic description 7ea enable all interrupt bit cleared to disable all interrupts. set to enable all interrupts. 6ec pca interrupt enable bit cleared to disable. set to enable. 5et2 timer 2 overflow interrupt enable bit cleared to disable timer 2 overflow interrupt. set to enable timer 2 overflow interrupt. 4es serial port enable bit cleared to disable serial port interrupt. set to enable serial port interrupt. 3et1 timer 1 overflow interrupt enable bit cleared to disable timer 1 overflow interrupt. set to enable timer 1 overflow interrupt. 2 ex1 external interrupt 1 enable bit cleared to disable external interrupt 1. set to enable external interrupt 1. 1et0 timer 0 overflow interrupt enable bit cleared to disable timer 0 overflow interrupt. set to enable timer 0 overflow interrupt. 0 ex0 external interrupt 0 enable bit cleared to disable external interrupt 0. set to enable external interrupt 0.
78 at89c51rd2/ed2 4235d?8051?12/03 table 54. ipl0 register ipl0 - interrupt priority register (b8h) reset value = x000 0000b bit addressable 76543210 - ppcl pt2l psl pt1l px1l pt0l px0l bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6ppcl pca interrupt priority bit refer to ppch for priority level. 5pt2l timer 2 overflow interrupt priority bit refer to pt2h for priority level. 4 psl serial port priority bit refer to psh for priority level. 3pt1l timer 1 overflow interrupt priority bit refer to pt1h for priority level. 2px1l external interrupt 1 priority bit refer to px1h for priority level. 1pt0l timer 0 overflow interrupt priority bit refer to pt0h for priority level. 0px0l external interrupt 0 priority bit refer to px0h for priority level.
79 at89c51rd2/ed2 4235d?8051?12/03 table 55. iph0 register iph0 - interrupt priority high register (b7h) reset value = x000 0000b not bit addressable 76543210 - ppch pt2h psh pt1h px1h pt0h px0h bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6ppch pca interrupt priority high bit. ppch ppcl priority level 0 0 lowest 01 10 1 1 highest 5pt2h timer 2 overflow interrupt priority high bit pt2h pt2l priority level 0 0 lowest 01 10 1 1 highest 4psh serial port priority high bit psh psl priority level 0 0 lowest 0 1 1 0 1 1 highest 3pt1h timer 1 overflow interrupt priority high bit pt1h pt1l priority level 0 0 lowest 01 10 1 1 highest 2px1h external interrupt 1 priority high bit px1h px1l priority level 0 0 lowest 01 10 1 1 highest 1pt0h timer 0 overflow interrupt priority high bit pt0h pt0l priority level 0 0 lowest 0 1 10 1 1 highest 0px0h external interrupt 0 priority high bit px0h px0l priority level 0 0 lowest 01 10 1 1 highest
80 at89c51rd2/ed2 4235d?8051?12/03 table 56. ien1 register ien1 - interrupt enable register (b1h) reset value = xxxx x000b bit addressable 76543210 -----espi-kbd bit number bit mnemonic description 7- reserved 6- reserved 5- reserved 4- reserved 3- reserved 2 espi spi interrupt enable bit cleared to disable spi interrupt. set to enable spi interrupt. 1 reserved 0kbd keyboard interrupt enable bit cleared to disable keyboard interrupt. set to enable keyboard interrupt.
81 at89c51rd2/ed2 4235d?8051?12/03 table 57. ipl1 register ipl1 - interrupt priority register (b2h) reset value = xxxx x000b bit addressable 76543210 -----spiltwil kbdl bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6- reserved the value read from this bit is indeterminate. do not set this bit. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4- reserved the value read from this bit is indeterminate. do not set this bit. 3- reserved the value read from this bit is indeterminate. do not set this bit. 2spil spi interrupt priority bit refer to spih for priority level. 1- reserved the value read from this bit is indeterminate. do not set this bit. 0kbdl keyboard interrupt priority bit refer to kbdh for priority level.
82 at89c51rd2/ed2 4235d?8051?12/03 table 58. iph1 register iph1 - interrupt priority high register (b3h) reset value = xxxx x000b not bit addressable 76543210 -----spih-kbdh bit number bit mnemonic description 7- reserved the value read from this bit is indeterminate. do not set this bit. 6- reserved the value read from this bit is indeterminate. do not set this bit. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4- reserved the value read from this bit is indeterminate. do not set this bit. 3- reserved the value read from this bit is indeterminate. do not set this bit. 2spih spi interrupt priority high bit spih spil priority level 0 0 lowest 0 1 1 0 1 1 highest 1- reserved the value read from this bit is indeterminate. do not set this bit. 0kbdh keyboard interrupt priority high bit kb dh kbdl priority level 0 0 lowest 0 1 10 1 1 highest
83 at89c51rd2/ed2 4235d?8051?12/03 power management introduction two power reduction modes are implemented in the at89c51rd2/ed2. the idle mode and the power-down mode. these modes are detailed in the following sections. in addi- tion to these power reduction modes, the clocks of the core and peripherals can be dynamically divided by 2 usi ng the x2 mode detailed in section ?enhanced features?, page 18. idle mode idle mode is a power reduction mode that reduces the power consumption. in this mode, program execution halts. idle mode freezes the clock to the cpu at known states while the peripherals continue to be clocked. the cpu status before entering idle mode is preserved, i.e., the program counter and program status word register retain their data for the duration of idle mode. the contents of the sfrs and ram are also retained. the status of the port pins during idle mode is detailed in table 59. entering idle mode to enter idle mode, set the idl bit in pcon register (see table 60). the at89c51rd2/ed2 enters idle mode upon execution of the instruction that sets idl bit. the instruction that sets idl bit is the last instruction executed. note: if idl bit and pd bit are set simultaneously, the at89c51rd2/ed2 enters power-down mode. then it does not go in idle mode when exiting power-down mode. exiting idle mode there are two ways to exit idle mode: 1. generate an enabled interrupt. ? hardware clears idl bit in pcon register which restores the clock to the cpu. execution resumes with the interrupt service routine. upon completion of the interrupt service routine, program execution resumes with the instruction immediately following the instruction that activated idle mode. the general purpose flags (gf1 and gf0 in pcon register) may be used to indicate whether an interrupt occurred during normal operation or during idle mode. when idle mode is exited by an interrupt, the interrupt service routine may examine gf1 and gf0. 2. generate a reset. ? a logic high on the rst pin clears idl bit in pcon register directly and asynchronously. this restores the clock to the cpu. program execution momentarily resumes with the instruction immediately following the instruction that activated the idle mode and may continue for a number of clock cycles before the internal reset algorithm takes control. reset initializes the at89c51rd2/ed2 and vectors the cpu to address c:0000h. note: during the time that execution resumes, the internal ram cannot be accessed; however, it is possible for the port pins to be accessed. to avoid unexpected outputs at the port pins, the instruction immediately following the instruction that activated idle mode should not write to a port pin or to the external ram. power-down mode the power-down mode places the at89c51rd2/ed2 in a very low power state. power-down mode stops the oscillator, freezes all clock at known states. the cpu sta- tus prior to entering power-down mode is preserved, i.e., the program counter, program status word register retain their data for the duration of power-down mode. in addition,
84 at89c51rd2/ed2 4235d?8051?12/03 the sfr and ram contents are preserved. the status of the port pins during power- down mode is detailed in table 59. note: vcc may be reduced to as low as v ret during power-down mode to further reduce power dissipation. take care, however, that vdd is not reduced until power-down mode is invoked. entering power-down mode to enter power-down mode, set pd bit in pcon register. the at89c51rd2/ed2 enters the power-down mode upon execution of the instruction that sets pd bit. the instruction that sets pd bit is the last instruction executed. exiting power-down mode note: if vcc was reduced during the power-down mode, do not exit power-down mode until vcc is restored to the normal operating level. there are two ways to exit the power-down mode: 1. generate an enabled external interrupt. ? the at89c51rd2/ed2 provides capability to exit from power-down using int0#, int1#. hardware clears pd bit in pcon register which starts the oscillator and restores the clocks to the cpu and peripherals. using intx# input, execution resumes when the input is released (see figure 37). execution resumes with the interrupt service routine. upon completion of the interrupt service routine, program execution resumes with the instruction immediately following the instruction that activated power-down mode. note: the external interrupt used to exit power-down mode must be configured as level sensi- tive (int0# and int1#) and must be assigned the highest priority. in addition, the duration of the interrupt must be long enough to allow the oscillator to stabilize. the exe- cution will only resume when the interrupt is deasserted. note: exit from power-down by external interrupt does not affect the sfrs nor the internal ram content. figure 37. power-down exit waveform using int1:0# 2. generate a reset. ? a logic high on the rst pin clears pd bit in pcon register directly and asynchronously. this starts the oscillator and restores the clock to the cpu and peripherals. program execution momentarily resumes with the instruction immediately following the instruction that activated power-down mode and may continue for a number of clock cycles before the internal reset algorithm takes control. reset initializes the at89c51rd2/ed2 and vectors the cpu to address 0000h. note: during the time that execution resumes, the internal ram cannot be accessed; however, it is possible for the port pins to be accessed. to avoid unexpected outputs at the port int1:0# osc power-down phase oscillator restart phase active phase active phase
85 at89c51rd2/ed2 4235d?8051?12/03 pins, the instruction immediately following the instruction that activated the power-down mode should not write to a port pin or to the external ram. note: exit from power-down by reset redefines all the sfrs , but does not affect the internal ram content. table 59. pin conditions in special operating modes mode port 0 port 1 port 2 port 3 port 4 ale psen# reset floating high high high high high high idle (internal code) data data data data data high high idle (external code) floating data data data data high high power- down (internal code) data data data data data low low power- down (external code) floating data data data data low low
86 at89c51rd2/ed2 4235d?8051?12/03 registers table 60. pcon register pcon (s87:h) power configuration register reset value= xxxx 0000b 76543210 ----gf1gf0pd idl bit number bit mnemonic description 7-4 - reserved the value read from these bits is i ndeterminate. do not set these bits. 3gf1 general purpose flag 1 one use is to indicate whether an interrupt occurred during normal operation or during idle mode. 2gf0 general purpose flag 0 one use is to indicate whether an interrupt occurred during normal operation or during idle mode. 1pd power-down mode bit cleared by hardware when an interrupt or reset occurs. set to activate the power-down mode. if idl and pd are both set, pd takes precedence. 0idl idle mode bit cleared by hardware when an interrupt or reset occurs. set to activate the idle mode. if idl and pd are both set, pd takes precedence.
87 at89c51rd2/ed2 4235d?8051?12/03 hardware watchdog timer the wdt is intended as a recovery method in situations where the cpu may be sub- jected to software upset. the wdt consists of a 14-bit counter and the watchdog timer reset (wdtrst) sfr. the wdt is by default disabled from exiting reset. to enable the wdt, user must write 01eh and 0e1h in sequence to the wdtrst, sfr location 0a6h. when wdt is enabled, it will increment every machine cycle while the oscillator is running and there is no way to disable the wdt except through reset (either hardware reset or wdt overflow reset). when wdt overflows, it will drive an output reset high pulse at the rst-pin. using the wdt to enable the wdt, user must write 01eh and 0e1h in sequence to the wdtrst, sfr location 0a6h. when wdt is enabled, the user needs to service it by writing to 01eh and 0e1h to wdtrst to avoid wdt overflow. the 14-bit counter overflows when it reaches 16383 (3fffh) and this will reset t he device. when wdt is enabled, it will increment every machine cycle while the oscillator is running. this means the user must reset the wdt at least every 16383 machine cycle. to reset the wdt the user must write 01eh and 0e1h to wdtrst. wdtrst is a write only register. the wdt counter cannot be read or written. when wdt overflows, it will generate an output reset pulse at the rst-pin. the reset pulse duration is 96 x t clk periph , where t clk periph = 1/f clk periph . to make the best use of the wdt, it should be serviced in those sections of code that will periodically be executed within the time required to prevent a wdt reset. to have a more powerful wdt, a 2 7 counter has been added to extend the time-out capability, ranking from 16 ms to 2s @ f osca = 12 mhz. to manage this feature, refer to wdtprg register description, table 61. the wdtprg register should be configured before the wdt activation sequence, and can not be modified until next reset. table 61. wdtrst register wdtrst - watchdog reset register (0a6h) reset value = xxxx xxxxb write only, this sfr is used to reset/enable the wdt by writing 01eh then 0e1h in sequence. 76543210 --------
88 at89c51rd2/ed2 4235d?8051?12/03 table 62. wdtprg register wdtprg - watchdog timer out register (0a7h) reset value = xxxx x000 wdt during power-down and idle in power-down mode the oscillator stops, which means the wdt also stops. while in power-down mode the user does not need to service the wdt. there are 2 methods of exiting power-down mode: by a hardware reset or via a level activated external interrupt which is enabled prior to entering power-down mode. when power-down is exited with hardware reset, servicing the wdt should occur as it normally should whenever the at89c51rd2/ed2 is reset. exiting power-down with an interrupt is significantly differ- ent. the interrupt is held low long enough for the oscillator to stabilize. when the interrupt is brought high, the interrupt is serviced. to prevent the wdt from resetting the device while the interrupt pin is held low, the wdt is not started until the interrupt is pulled high. it is suggested that the wdt be reset during the interrupt service routine. to ensure that the wdt does not overflow within a few states of exiting of powerdown, it is better to reset the wdt just before entering powerdown. in the idle mode, the oscillator continues to run. to prevent the wdt from resetting the at89c51rd2/ed2 while in idle mode, the user should always set up a timer that will periodically exit idle, service the wdt, and re-enter idle mode. 76543210 -----s2s1s0 bit number bit mnemonic description 7- reserved the value read from this bit is undetermined. do not try to set this bit. 6- 5- 4- 3- 2s2 wdt time-out select bit 2 1s1 wdt time-out select bit 1 0s0 wdt time-out select bit 0 s2 s1 s0 selected time-out 000 (2 14 - 1) machine cycles, 16. 3 ms @ f osca =12 mhz 001 (2 15 - 1) machine cycles, 32.7 ms @ f osca =12 mhz 010 (2 16 - 1) machine cycles, 65. 5 ms @ f osca =12 mhz 011 (2 17 - 1) machine cycles, 131 ms @ f osca =12 mhz 100 (2 18 - 1) machine cycles, 262 ms @ f osca =12 mhz 101 (2 19 - 1) machine cycles, 542 ms @ f osca =12 mhz 110 (2 20 - 1) machine cycles, 1.05 ms @ f osca =12 mhz 111 (2 21 - 1) machine cycles, 2.09 ms @ f osca =12 mhz
89 at89c51rd2/ed2 4235d?8051?12/03 once ? mode (on- chip emulation) the once mode facilitates testing and debugging of systems using at89c51rd2/ed2 without removing the circuit from the board. the once mode is invoked by driving cer- tain pins of the at89c51rd2/ed2; the following sequence must be exercised: pull ale low while the device is in reset (rst high) and psen is high. hold ale low as rst is deactivated. while the at89c51rd2/ed2 is in once mode, an emulator or test cpu can be used to drive the circuit. table 63 shows the status of the port pins during once mode. normal operation is restored when normal reset is applied. table 63. external pin status during once mode ale psen port 0 port 1 port 2 port 3 port i2 xtala1/2 xtalb1/2 weak pull-up weak pull-up float weak pull-up weak pull-up weak pull-up float active active
90 at89c51rd2/ed2 4235d?8051?12/03 power-off flag the power-off flag allows the user to distinguish between a ?cold start? reset and a ?warm start? reset. a cold start reset is the one induced by v cc switch-on. a warm start reset occurs while v cc is still applied to the device and could be generated for example by an exit from power-down. the power-off flag (pof) is located in pcon register (table 64). pof is set by hard- ware when v cc rises from 0 to its nominal voltage. the pof can be set or cleared by software allowing the user to determine the type of reset. table 64. pcon register pcon - power control register (87h) reset value = 00x1 0000b not bit addressable 76543210 smod1 smod0 - pof gf1 gf0 pd idl bit number bit mnemonic description 7smod1 serial port mode bit 1 set to select double baud rate in mode 1, 2 or 3. 6smod0 serial port mode bit 0 cleared to select sm0 bit in scon register. set to select fe bit in scon register. 5- reserved the value read from this bit is indeterminate. do not set this bit. 4pof power-off flag cleared by software to recognize the next reset type. set by hardware when v cc rises from 0 to its nominal voltage. can also be set by software. 3gf1 general-purpose flag cleared by user for general-purpose usage. set by user for general-purpose usage. 2gf0 general-purpose flag cleared by user for general-purpose usage. set by user for general-purpose usage. 1pd power-down mode bit cleared by hardware when reset occurs. set to enter power-down mode. 0idl idle mode bit cleared by hardware when interrupt or reset occurs. set to enter idle mode.
91 at89c51rd2/ed2 4235d?8051?12/03 reduced emi mode the ale signal is used to demultiplex address and data buses on port 0 when used with external program or data memory. nevertheless, during internal code execution, ale signal is still generated. in order to reduce emi, ale signal can be disabled by setting ao bit. the ao bit is located in auxr register at bit location 0. as soon as ao is set, ale is no longer output but remains active during movx and movc instructions and external fetches. during ale disabling, ale pin is weakly pulled high. table 65. auxr register auxr - auxiliary register (8eh) reset value = xx00 10?hsb. xram?0b not bit addressable 76543210 dpu - m0 xrs2 xrs1 xrs0 extram ao bit number bit mnemonic description 7dpu disable weak pull-up cleared by software to activate the permanent weak pull-up (default) set by software to disable the w eak pull-up (reduce power consumption) 6- reserved the value read from this bit is indeterminate. do not set this bit. 5m0 pulse length cleared to stretch movx control: the rd and the wr pulse length is 6 clock periods (default). set to stretch movx control: the rd and the wr pulse length is 30 clock periods. 4xrs2 xram size xrs2 xrs1 xrs0 xram size 0 0 0 256 bytes 0 0 1 512 bytes 0 1 0 768 bytes(default) 0 1 1 1024 bytes 1 0 0 1792 bytes 3xrs1 2xrs0 1extram extram bit cleared to access internal xram using movx @ ri/ @ dptr. set to access external memory. programmed by hardware after power-up regarding hardware security byte (hsb), default setting, xram selected. 0ao ale output bit cleared, ale is emitted at a constant rate of 1/6 the oscillator frequency (or 1/3 if x2 mode is used) (default). set, ale is active only during a movx or movc instruction is used.
92 at89c51rd2/ed2 4235d?8051?12/03 eeprom data memory this feature is available only for the AT89C51ED2 device. the 2k bytes on-chip eeprom memory block is located at addresses 0000h to 07ffh of the xram/eram memory space and is selected by setting control bits in the eecon register. a read or write access to the eeprom memory is done with a movx instruction. write data data is written by byte to the eeprom memory block as for an external ram memory. the following procedure is used to write to the eeprom memory: check eebusy flag if the user application interrupts routines use xram memory space: save and disable interrupts. load dptr with the address to write store a register with the data to be written set bit eee of eecon register execute a movx @dptr, a clear bit eee of eecon register restore interrupts. eebusy flag in eecon is then set by hardware to indicate that programming is in progress and that the eeprom segment is not available for reading or writing. the end of programming is indicated by a hardware clear of the eebusy flag. figure 38 represents the optimal write sequence to the on-chip eeprom data memory.
93 at89c51rd2/ed2 4235d?8051?12/03 figure 38. recommended eeprom data write sequence eeprom data write sequence data write dptr= address acc= data exec: movx @dptr, a last byte to load? eeprom mapping eecon = 00h (eee=0) save & disable it ea= 0 restore it eeprom data mapping eecon = 02h (eee=1) eebusy cleared?
94 at89c51rd2/ed2 4235d?8051?12/03 read data the following procedure is used to read the data stored in the eeprom memory: check eebusy flag if the user application interrupts routines use xram memory space: save and disable interrupts. load dptr with the address to read set bit eee of eecon register execute a movx a, @dptr clear bit eee of eecon register restore interrupts. figure 39. recommended eeprom data read sequence eeprom data read sequence data read dptr= address acc= data exec: movx a, @dptr last byte to read? eeprom data mapping eecon = 02h (eee=1) eeprom data mapping eecon = 00h (eee = 0 save & disable it ea= 0 restore it eebusy cleared?
95 at89c51rd2/ed2 4235d?8051?12/03 registers table 66. eecon register eecon (0d2h) eeprom control register reset value = xxxx xx00b not bit addressable 76543210 ------eeeeebusy bit number bit mnemonic description 7 - 2 - reserved the value read from this bit is indeterminate. do not set this bit. 1eee enable eeprom space bit set to map the eeprom space during movx instructions (write or read to the eeprom. clear to map the xram space during movx. 0eebusy programming busy flag set by hardware when programming is in progress. cleared by hardware when programming is done. can not be set or cleared by software.
96 at89c51rd2/ed2 4235d?8051?12/03 flash/eeprom memory the flash memory increases eeprom and rom functionality with in-circuit electrical erasure and programming. it contains 64k bytes of program memory organized respec- tively in 512 pages of 128 bytes. this memory is both parallel and serial in-system programmable (isp). isp allows devices to alter their own program memory in the actual end product under software control. a default serial loader (bootloader) program allows isp of the flash. the programming does not require external dedicated programming voltage. the nec- essary high programming voltage is generated on-chip using the standard v cc pins of the microcontroller. features flash eeprom internal program memory boot vector allows user provided flash loader code to reside anywhere in the flash memory space. this configuration provides flexibility to the user. default loader in boot rom allows programming via the serial port without the need of a user provided loader. up to 64k bytes external program memory if the internal program memory is disabled (ea = 0). programming and erasing voltage with standard power supply read/programming/erase: ? byte-wise read without wait state ? byte or page erase and programming (10 ms) typical programming time (64k bytes) is 22s with on chip serial bootloader parallel programming with 87c51 compatible hardware interface to programmer programmable security for the code in the flash 100k write cycles 10 years data retention flash programming and erasure the 64-k byte flash is programmed by bytes or by pages of 128 bytes. it is not neces- sary to erase a byte or a page before programming. the programming of a byte or a page includes a self erase before programming. there are three methods of programming the flash memory: 1. the on-chip isp bootloader may be invoked which will use low level routines to program the pages. the interface used for serial downloading of flash is the uart. 2. the flash may be programmed or erased in the end-user application by calling low-level routines through a common entry point in the boot rom. 3. the flash may be programmed using the parallel method by using a conven- tional eprom programmer. the parallel programming method used by these devices is similar to that used by eprom 87c51 but it is not identical and the commercially available programmers need to have support for the at89c51rd2/ed2. the bootloader and the application programming interface (api) routines are located in the boot rom.
97 at89c51rd2/ed2 4235d?8051?12/03 flash registers and memory map the at89c51rd2/ed2 flash memory uses several registers for its management: hardware registers can only be accessed through the parallel programming modes which are handled by the parallel programmer. software registers are in a special page of the flash memory which can be accessed through the api or with the parallel programming modes. this page, called "extra flash memory", is not in the internal flash program memory addressing space. hardware register the only hardware register of the at89c51rd2/ed2 is called hardware security byte (hsb). table 67. hardware security byte (hsb) boot loader jump bit (bljb) one bit of the hsb, the bljb bit, is used to force the boot address: when this bit is programmed (?1? value) the boot address is 0000h. when this bit is unprogrammed (?1? value) the boot address is f800h. by default, this bit is unprogrammed and the isp is enabled. flash memory lock bits the three lock bits provide different levels of protection for the on-chip code and data when programmed as shown in table 68. 76543210 x2 bljb osc - xram lb2 lb1 lb0 bit number bit mnemonic description 7x2 x2 mode programmed (?0? value) to force x2 mode (6 clocks per instruction) after reset. unprogrammed (?1? value) to force x1 mode, standard mode, after reset (default). 6bljb boot loader jump bit unprogrammed (?1? value) to start the user?s application on next reset at address 0000h. programmed (?0? value) to start the boot loader at address f800h on next reset (default). 5osc oscillator bit programmed to allow oscillator b at startup unprogrammed this bit to allow oscillator a at startup (default). 4- reserved 3xram xram config bit (only programmable by programmer tools) programmed to inhibit xram. unprogrammed, this bit to valid xram (default). 2-0 lb2-0 user memory lock bits (only programmable by programmer tools) see table 68
98 at89c51rd2/ed2 4235d?8051?12/03 table 68. program lock bits note: u: unprogrammed or "one" level. p: programmed or "zero" level. x: do not care warning: security level 2 and 3 should only be programmed after flash and code verification. these security bits protect the code access through the parallel programming interface. they are set by default to level 4. the code access through the isp is still possible and is controlled by the "software security bits" which are stored in the extra flash memory accessed by the isp firmware. to load a new application with the parallel programmer, a chip erase must first be done. this will set the hsb in its inactive state and will erase the flash memory. the part ref- erence can always be read using flash parallel programming modes. default values the default value of the hsb provides parts ready to be programmed with isp: bljb: programmed force isp operation. x2: unprogrammed to force x1 mode (standard mode). xram: unprogrammed to valid xram lb2-0: security level four to protect the code from a parallel access with maximum security. software registers several registers are used in factory and by parallel programmers. these values are used by atmel isp. these registers are in the "extra flash memory" part of the flash memory. this block is also called "xaf" or extra array flash. they are accessed in the following ways: commands issued by the parallel memory programmer. commands issued by the isp software. calls of api issued by the application software. several software registers are described in table 69. program lock bits protection description security level lb0 lb1 lb2 1 u u u no program lock features enabled. 2puu movc instruction executed from external program memory is disabled from fetching code bytes from internal memory, ea is sampled and latched on reset, and further parallel programming of the on chip code memory is disabled. isp and software programming with api are still allowed. 3xpu same as 2, also verify code memory through parallel programming interface is disabled. 4 x x p same as 3, also external execution is disabled (default).
99 at89c51rd2/ed2 4235d?8051?12/03 table 69. default values after programming the part by isp, the bsb must be cleared (00h) in order to allow the application to boot at 0000h. the content of the software security byte (ssb) is described in table 70 and table 71. to assure code protection from a parallel access, the hsb must also be at the required level. table 70. software security byte the two lock bits provide different levels of protection for the on-chip code and data, when programmed as shown in table 71. mnemonic definition default value description sbv software boot vector fch bsb boot status byte 0ffh ssb software security byte ffh copy of the manufacturer code 58h atmel copy of the device id #1: family code d7h c51 x2, electrically erasable copy of the device id #2: memories size and type ech at89c51rd2/ed2 64kb copy of the device id #3: name and revision efh at89c51rd2/ed2 64kb, revision 0 76543210 ------lb1lb0 bit number bit mnemonic description 7- reserved do not clear this bit. 6- reserved do not clear this bit. 5- reserved do not clear this bit. 4- reserved do not clear this bit. 3- reserved do not clear this bit. 2- reserved do not clear this bit. 1-0 lb1-0 user memory lock bits see table 71
100 at89c51rd2/ed2 4235d?8051?12/03 table 71. program lock bits of the ssb note: u: unprogrammed or "one" level. p: programmed or "zero" level. x: do not care warning: security level 2 and 3 should only be programmed after flash and code verification. flash memory status at89c51rd2/ed2 parts are delivered in standard with the isp rom bootloader. after isp or parallel programming, the possible contents of the flash memory are sum- marized in figure 40: figure 40. flash memory possible contents memory organization when the ea pin is high, the processor fetches instructions from internal program flash. if the ea pin is tied low, all program memory fetches are from external memory. program lock bits protection description security level lb0 lb1 1 u u no program lock features enabled. 2 p u isp programming of the flash is disabled. 3 x p same as 2, also verify through isp programming interface is disabled. 0000h virgin default after isp after parallel programming after parallel programming after parallel programming application application virgin after isp or dedicated isp dedicated isp application virgin or application virgin or application ffffh
101 at89c51rd2/ed2 4235d?8051?12/03 bootloader architecture introduction the bootloader manages communication according to a specifically defined protocol to provide the whole access and service on flash memory. furthermore, all accesses and routines can be called from the user application. figure 41. diagram context description acronyms isp: in-system programming sbv: software boot vector bsb: boot status byte ssb: software security bit hw: hardware byte bootloader flash memor y access via specific protocol access from user application
102 at89c51rd2/ed2 4235d?8051?12/03 functional description figure 42. bootloader functional description on the above diagram, the on-chip bootloader processes are: isp communication management the purpose of this process is to manage the communication and its protocol between the on-chip bootloader and a external device. the on-chip rom implements a serial protocol (see section ?bootloader protocol?). this process translate serial communica- tion frame (uart) into flash memory access (read, write, erase, etc.). user call management several application program interface (api) calls are available for use by an application program to permit selective erasing and programming of flash pages. all calls are made through a common interface (api calls), included in the rom bootloader. the program- ming functions are selected by setting up the microcontroller?s registers before making a call to a common entry point (0xfff0). results are returned in the registers. the pur- pose on this process is to translate the registers values into internal flash memory management. flash memory management this process manages low level access to flash memory (performs read and write access). isp communication management user application specific protocol communication management flash memory external host with flash memory user call management (api)
103 at89c51rd2/ed2 4235d?8051?12/03 bootloader functionality the bootloader can be activated by two means: hardware conditions or regular boot process. the hardware conditions (ea = 1, psen = 0) during the reset# falling edge force the on-chip bootloader execution. this allows an application to be built that will normally execute the end user?s code but can be manually forced into default isp operation. as psen is a an output port in normal operating mode after reset, user application should take care to release psen after falling edge of reset signal. the hardware condi- tions are sampled at reset signal falling edge, thus they can be released at any time when reset input is low. to ensure correct microcontroller startup, the psen pin should not be tied to ground during power-on (see figure 43). figure 43. hardware conditions typical sequence during power-on. the on-chip bootloader boot process is shown figure 44. vcc psen rst table 72. bootloader process description purpose hardware conditions the hardware conditions force the bootloader execution whatever bljb, bsb and sbv values. bljb the boot loader jump bit forces the application execution. bljb = 0 => bootloader execution bljb = 1 => application execution the bljb is a fuse bit in the hardware byte. it can be modified by hardware (programmer) or by software (api). note: the bljb test is performed by hardware to prevent any program execution. sbv the software boot vector contains the high address of customer bootloader stored in the application. sbv = fch (default value) if no customer bootloader in user flash. note: the customer bootloader is called by jmp [sbv]00h instruction.
104 at89c51rd2/ed2 4235d?8051?12/03 boot process figure 44. bootloader process reset hardware condition? bljb!= 0 ? user application hardware software fcon = 00h fcon = f0h fcon = 00h ? atmel boot loader user boot loader yes = hardware boot f800h bljb = 1 bsb = 00h ? sbv = fch ? pc = 0000h pc= [sbv]00h conditions bljb = 0 if bljb = 0 then enboot bit (auxr1) is set else enboot bit (auxr1) is cleared enboot = 1 enboot = 0 yes (psen = 0, ea = 1, and ale =1 or not connected)
105 at89c51rd2/ed2 4235d?8051?12/03 isp protocol description physical layer the uart used to transmit information has the following configuration: character: 8-bit data parity: none stop: 2 bits flow control: none baudrate: autobaud is performed by the bootloader to compute the baudrate chosen by the host. frame description the serial protocol is based on the intel hex-type records. intel hex records consist of ascii characters used to represent hexadecimal values and are summarized below. figure 45. intel hex type frame record mark: record mark is the start of frame. this field must contain ?:?. reclen: reclen specifies the number of bytes of information or data which follows the record type field of the record. load offset: load offset specifies the 16-bit starting load offset of the data bytes, therefore this field is used only for data program record (see section ?isp commands summary?). record type: record type specifies the command type. this field is used to interpret the remaining information within the frame. the encoding for all the current record types is described in section ?isp commands summary?. data/info: data/info is a variable length field. it consists of zero or more bytes encoded as pairs of hexadecimal digits. the meaning of data depends on the record type . checksum: the two?s complement of the 8-bit bytes that result from converting each pair of ascii hexadecimal digits to one byte of binary, and including the reclen field to and including the last byte of the data/info field. therefore, the sum of all the ascii pairs in a record after converting to binary, from the reclen field to and including the checksum field, is zero. record record load data mark ?:? reclen offset type or info checksum 1-byte 1-byte 2-bytes 1-byte n-bytes 1-byte
106 at89c51rd2/ed2 4235d?8051?12/03 functional description software security bits (ssb) the ssb protects any flash access from isp command. the command "program software security bit" can only write a higher priority level. there are three levels of security: level 0: no_security (ffh) this is the default level. from level 0, one can write level 1 or level 2. level 1: write_security (feh) for this level it is impossible to write in the flash memory, bsb and sbv. the bootloader returns ?p? on write access. from level 1, one can write only level 2. level 2: rd_wr_security (fch the level 2 forbids all read and write accesses to/from the flash/eeprom memory. the bootloader returns ?l? on read or write access. only a full chip erase in parallel mode (using a programmer) or isp command can reset the software security bits. from level 2, one cannot read and write anything. table 73. software security byte behavior level 0 level 1 level 2 flash/eeprom any access allowed read-only access allowed any access not allowed fuse bit any access allowed read-only access allowed any access not allowed bsb & sbv any access allowed read-only access allowed any access not allowed ssb any access allowed write level 2 allowed read-only access allowed manufacturer info read-only access allowed read-only acce ss allowed read-only access allowed bootloader info read-only access allowed read- only access allowed read-only access allowed erase block allowed not allowed not allowed full chip erase allowed allowed allowed blank check allowed allowed allowed
107 at89c51rd2/ed2 4235d?8051?12/03 full chip erase the isp command "full chip erase" erases all user flash memory (fills with ffh) and sets some bytes used by the bootloader at their default values: bsb = ffh sbv = fch ssb = ffh the full chip erase does not affect the bootloader. checksum error when a checksum error is detected, send ?x? followed with cr&lf. flow description overview an initialization step must be performed after each reset. after microcontroller reset, the bootloader waits for an autobaud sequence (see section ?autobaud performances?). when the communication is initialized, the protocol depends on the record type requested by the host. flip, a software utility to implement isp progr amming with a pc, is available from the atmel web site. communication initialization the host initializes the communication by sending a ?u? character to help the bootloader to compute the baudrate (autobaud). figure 46. initialization host bootloader "u" performs autobaud init communication if (not received "u") "u" communication opened else sends back ?u? charac ter
108 at89c51rd2/ed2 4235d?8051?12/03 autobaud performances the isp feature allows a wide range of baud rates in the user application. it is also adaptable to a wide range of oscillator frequencies. this is accomplished by measuring the bit-time of a single bit in a received character. this information is then used to pro- gram the baud rate in terms of timer counts based on the oscillator frequency. the isp feature requires that an initial character (an uppercase u) be sent to the at89c51rd2/ed2 to establish the baud rate. table show the autobaud capability. command data stream protocol all commands are sent using the same flow. each frame sent by the host is echoed by the bootloader. table 74. autobaud performances frequency (mhz) baudrate (khz) 1.8432 2 2.4576 3 3.6864 4 5 6 7.3728 2400 ok ok ok ok ok ok ok ok ok 4800 ok - okokokokokokok 9600 ok - okokokokokokok 19200 ok - ok ok ok - - ok ok 38400 - - ok ok - ok ok ok 57600 ----ok---ok 115200 --------ok frequency (mhz) baudrate (khz) 8 10 11.0592 12 14.746 16 20 24 26.6 2400 ok ok ok ok ok ok ok ok ok 4800 ok ok ok ok ok ok ok ok ok 9600 ok ok ok ok ok ok ok ok ok 19200 okokokokokokokokok 38400 - - okokokokokokok 57600 - - ok - ok ok ok ok ok 115200 --ok-ok----
109 at89c51rd2/ed2 4235d?8051?12/03 figure 47. command flow bootloader ":" sends first character of the frame if (not received ":") sends frame (made of 2 ascii gets frame, and sends back echo for each received byte host else ":" sends echo and start reception characters per byte) echo analysis
110 at89c51rd2/ed2 4235d?8051?12/03 write/program commands description this flow is common to the following frames: flash/eeprom programming data frame eof or atmel frame (only programming atmel frame) config byte programming data frame baud rate frame figure 48. write/program flow example host bootloader write command ?x? & cr & lf no_security wait write command checksum error wait programming send security error send command_ok send write command wait checksum error wait command_ok wait security error or command aborted command finished send checksum error command aborted ?p? & cr & lf or ?.? & cr & lf host : 01 0010 00 55 9a bootloader : 01 0010 00 55 9a . cr lf programming data (write 55h at address 0010h in the flash) host : 02 0000 03 05 01 f5 bootloader : 02 0000 03 05 01 f5. cr lf programming atmel function (write ssb to level 2) host : 03 0000 03 06 00 55 9f bootloader : 03 0000 03 06 00 55 9f . cr lf writing frame (write bsb to 55h)
111 at89c51rd2/ed2 4235d?8051?12/03 blank check command description figure 49. blank check flow example host bootloader blank check command ?x? & cr & lf flash blank wait blank check command send first address send command_ok send blank check command wait checksum error wait address not erased wait command_ok or command aborted command finished send checksum error command finished ?.? & cr & lf or address & cr & lf not erased checksum error host : 05 0000 04 0000 7fff 01 78 bootloader : 05 0000 04 0000 7fff 01 78 . cr lf blank check ok bootloader : 05 0000 04 0000 7fff 01 70 x cr lf cr lf blank check with checksum error host : 05 0000 04 0000 7fff 01 70 bootloader : 05 0000 04 0000 7fff 01 78 xxxx cr lf blank check ok at address xxxx host : 05 0000 04 0000 7fff 01 78
112 at89c51rd2/ed2 4235d?8051?12/03 display data description figure 50. display flow note: the maximum size of block is 400h. to read more than 400h bytes, the host must send a new command. example host bootloader display command ?x? & cr & lf rd_wr_security wait display command read data send security error send display data send display command wait checksum error wait display data wait security error or command aborted command finished send checksum error command aborted ?l? & cr & lf or "address = " all data read complet frame "reading value" cr & lf all data read all data read command finished checksum error host : 05 0000 04 0000 0020 00 d7 bootloader : 05 0000 04 0000 0020 00 d7 bootloader 0000=-----data------ cr lf (16 data) bootloader 0010=-----data------ cr lf (16 data) bootloader 0020=data cr lf ( 1 data) display data from address 0000h to 0020h
113 at89c51rd2/ed2 4235d?8051?12/03 read function description this flow is similar for the following frames: reading frame eof frame/ atmel frame (only reading atmel frame) figure 51. read flow example host bootloader read command ?x? & cr & lf rd_wr_security wait read command read value send security error send data read send read command wait checksum error wait value of data wait security error or command aborted command finished send checksum error command aborted ?l? & cr & lf or ?value? & ?.? & cr & lf checksum error host : 02 0000 05 07 02 f0 bootloader : 02 0000 05 07 02 f0 value . cr lf host : 02 0000 01 02 00 fb bootloader : 02 0000 01 02 00 fb value . cr lf read function (read sbv) atmel read function (read bootloader version)
114 at89c51rd2/ed2 4235d?8051?12/03 isp commands summary table 75. isp commands summary command command name data[0] data[1] command effect 00h program code program nb code byte. bootloader will accept up to 128 (80h) data bytes. the data bytes should be 128 byte page flash boundary. 03h write function 01h 00h erase block0 (0000h-1fffh) 20h erase block1 (2000h-3fffh) 40h erase block2 (4000h-7fffh) 80h erase block3 (8000h- bfffh) c0h erase block4 (c000h- ffffh) 03h 00h hardware reset 04h 00h erase sbv & bsb 05h 00h program ssb level 1 01h program ssb level 2 06h 00h program bsb (value to write in data[2]) 01h program sbv (value to write in data[2]) 07h - full chip erase (this command needs about 6 sec to be executed) 0ah 04h program bljb fuse (value to write in data[2]) 08h program x2 fuse (value to write in data[2]) 04h display function data[0:1] = start address data [2:3] = end address data[4] = 00h:display code data[4] = 01h: blank check data[4] = 02h: display eeprom display code blank check display eeprom data 05h read function 00h 00h manufacturer id 01h device id #1 02h device id #2 03h device id #3 07h 00h read ssb 01h read bsb 02h read sbv 06h read extra byte 0bh 00h read hardware byte 0eh 00h read device boot id1 01h read device boot id2 0fh 00h read bootloader version 07h program eeprom data program nn eeprom data byte. bootloader will accept up to 128 (80h) data bytes.
115 at89c51rd2/ed2 4235d?8051?12/03 api call description the iap allows to reprogram a microcontroller on-chip flash memory without removing it from the system and while the embedded application is running. the user application can call some application programming interface (api) routines allowing iap. these api are executed by the bootloader. to call the corresponding api, the user must use a set of flash_api routines which can be linked with the application. example of flash_api routines are available on the atmel web site on the software appli- cation note: c flash drivers for the at89c51rd2/ed2 the api calls description and arguments are shown in table 76. process the application selects an api by setting r1, acc, dptr0 and dptr1 registers. all calls are made through a common interface ?user_call? at the address fff0h. the jump at the user_call must be done by lcall instruction to be able to come- back in the application. before jump at the user_call, the bit enboot in auxr1 register must be set. constraints the interrupts are not disabled by the bootloader. interrupts must be disabled by user prior to jump to the user_call, then re-enabled when returning. interrupts must also be disabled before accessing eeprom data then re-enabled after. the user must take care of hardware watchdog before launching a flash operation. table 76. api call summary command r1 a dptr0 dptr1 returned value command effect read manuf id 00h xxh 0000h xxh acc = manufacturer id read manufacturer identifier read device id1 00h xxh 0001h xxh acc = device id 1 read device identifier 1 read device id2 00h xxh 0002h xxh acc = device id 2 read device identifier 2 read device id3 00h xxh 0003h xxh acc = device id 3 read device identifier 3 erase block 01h xxh dph = 00h 00h acc = dph erase block 0 dph = 20h erase block 1 dph = 40h erase block 2 address of byte to program program one data byte in user flash xxh erase software boot vector and boot status byte. (sbv = fch and bsb = ffh)
116 at89c51rd2/ed2 4235d?8051?12/03 program ssb 05h xxh dph = 00h dpl = 00h 00h acc = ssb value set ssb level 1 dph = 00h dpl = 01h set ssb level 2 dph = 00h dpl = 10h set ssb level 0 dph = 00h dpl = 11h set ssb level 1 program bsb 06h new bsb value 0000h xxh none program boot status byte program sbv 06h new sbv value 0001h xxh none program software boot vector read ssb 07h xxh 0000h xxh acc = ssb read software security byte read bsb 07h xxh 0001h xxh acc = bsb read boot status byte read sbv 07h xxh 0002h xxh acc = sbv read software boot vector program data page 09h number of byte to program address of the first byte to program in the flash memory address in xram of the first data to program acc = 0: done program up to 128 bytes in user flash. remark: number of bytes to program is limited such as the flash write remains in a single 128 bytes page. hence, when acc is 128, valid values of dpl are 00h, or, 80h. program x2 fuse 0ah fuse value 00h or 01h 0008h xxh none program x2 fuse bit with acc program bljb fuse 0ah fuse value 00h or 01h 0004h xxh none program bljb fuse bit with acc read hsb 0bh xxh xxxxh xxh acc = hsb read hardware byte read boot id1 0eh xxh dpl = 00h xxh acc = id1 read boot id1 read boot id2 0eh xxh dpl = 01h xxh acc = id2 read boot id2 read boot version 0fh xxh xxxxh xxh acc = boot_version read bootloader version table 76. api call summary (continued) command r1 a dptr0 dptr1 returned value command effect
117 at89c51rd2/ed2 4235d?8051?12/03 e lectrical characteristics absolute maximum ratings dc parameters for standard voltage i = industrial ........................................................-40 c to 85 c storage temperature .................................... -65 c to + 150 c voltage on v cc to v ss ......................................-0.5v to + 6.5v vvoltage on any pin to v ss .......................-0.5v to v cc + 0.5v power dissipation ........................................................... 1 w (2) note: stresses at or above 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 condi- tions above those indicated in the operational sections of this specification is not implied. exposure to absolute maximum rating conditions may affect device reliability. power dissipation is based on the maximum allow- able die temperature and the thermal resistance of the package. t a = -40 c to +85 c; v ss = 0v; v cc =2.7v to 5.5v and f = 0 to 40 mhz (both internal and external code execution) v cc =4.5v to 5.5v and f = 0 to 60 mhz (internal code execution only) symbol parameter min typ max unit test conditions v il input low voltage -0.5 0.2 v cc - 0.1 v v ih input high voltage except rst, xtal1 0.2 v cc + 0.9 v cc + 0.5 v v ih1 input high voltage rst, xtal1 0.7 v cc v cc + 0.5 v v ol output low voltage, ports 1, 2, 3, 4 (6) 0.3 0.45 1.0 v v v v cc = 4.5v to 5.5v i ol = 100 a (4) i ol = 1.6 ma (4) i ol = 3.5 ma (4) 0.45 v v cc = 2.7v to 5.5v i ol = 0.8 ma (4) v ol1 output low voltage, port 0, ale, psen (6) 0.3 0.45 1.0 v v v v cc = 4.5v to 5.5v i ol = 200 a (4) i ol = 3.2 ma (4) i ol = 7.0 ma (4) 0.45 v v cc = 2.7v to 5.5v i ol = 1.6 ma (4) v oh output high voltage, ports 1, 2, 3, 4 v cc - 0.3 v cc - 0.7 v cc - 1.5 v v v v cc = 5v 10% i oh = -10 a i oh = -30 a i oh = -60 a 0.9 v cc v v cc = 2.7v to 5.5v i oh = -10 a
118 at89c51rd2/ed2 4235d?8051?12/03 notes: 1. operating i cc is measured with all output pins disconnected; xtal1 driven with t clch , t chcl = 5 ns (see figure 55), v il = v ss + 0.5v, v ih = v cc - 0.5v; xtal2 n.c.; ea = rst = port 0 = v cc . i cc would be slightly higher if a crystal oscillator used (see figure 52). 2. idle i cc is measured with all output pins disconnected; xtal1 driven with t clch , t chcl = 5 ns, v il = v ss + 0.5v, v ih = v cc - 0.5v; xtal2 n.c; port 0 = v cc ; ea = rst = v ss (see figure 53). 3. power-down i cc is measured with all output pins disconnected; ea = v ss , port 0 = v cc ; xtal2 nc.; rst = v ss (see fig- ure 54). 4. capacitance loading on ports 0 and 2 may cause spurious noise pulses to be superimposed on the v ols of ale and ports 1 and 3. the noise is due to external bus capacitance discharging into the port 0 and port 2 pins when these pins make 1 to 0 transitions during bus operation. in the worst cases (capacitive loading 100 pf), the noise pulse on the ale line may exceed 0.45v with maxi v ol peak 0.6v. a schmitt trigger use is not necessary. 5. typical values are based on a limited number of samples and are not guaranteed. the values listed are at room temperature and 5v. 6. under steady state (non-transient) conditions, i ol must be externally limited as follows: maximum i ol per port pin: 10 ma maximum i ol per 8-bit port: port 0: 26 ma ports 1, 2 and 3: 15 ma maximum total i ol for all output pins: 71 ma if i ol exceeds the test condition, v ol may exceed the related specification. pins are not guaranteed to sink current greater than the listed test conditions. v oh1 output high voltage, port 0, ale, psen v cc - 0.3 v cc - 0.7 v cc - 1.5 v v v v cc = 5v 10% i oh = -200 a i oh = -3.2 ma i oh = -7.0 ma 0.9 v cc v v cc = 2.7v to 5.5v i oh = -10 a r rst rst pull-down resistor 50 200 (5) 250 k ? i il logical 0 input current ports 1, 2, 3, 4 and 5 -50 av in = 0.45v i li input leakage current 10 a 0.45v < v in < v cc i tl logical 1 to 0 transition current, ports 1, 2, 3, 4 -650 av in = 2.0v c io capacitance of i/o buffer 10 pf f c = 3 mhz t a = 25 c i pd power-down current 75 150 a2.7 < v cc < 5.5v (3) i ccop power supply current on normal mode 0.4 x frequency (mhz) + 5 ma v cc = 5.5v (1) i ccidle power supply current on idle mode 0.3 x frequency (mhz) + 5 ma v cc = 5.5v (2) i ccwrite power supply current on flash or eedata write 0.8 x frequency (mhz) + 15 ma v cc = 5.5v t write flash or eedata programming time 7 17 ms 2.7 < v cc < 5.5v t a = -40 c to +85 c; v ss = 0v; v cc =2.7v to 5.5v and f = 0 to 40 mhz (both internal and external code execution) v cc =4.5v to 5.5v and f = 0 to 60 mhz (internal code execution only) (continued) symbol parameter min typ max unit test conditions
119 at89c51rd2/ed2 4235d?8051?12/03 figure 52. i cc test condition, active mode figure 53. i cc test condition, idle mode figure 54. i cc test condition, power-down mode figure 55. clock signal waveform for i cc tests in active and idle modes ea v cc v cc i cc (nc) clock signal v cc all other pins are disconnected. rst xtal2 xtal1 v ss v cc p0 rst ea xtal2 xtal1 v ss v cc v cc i cc (nc) p0 v cc all other pins are disconnected. clock signal rst ea xtal2 xtal1 v ss v cc v cc i cc (nc) p0 v cc all other pins are disconnected. v cc -0.5v 0.45v 0.7v cc 0.2v cc -0.1 t clch t chcl t clch = t chcl = 5ns.
120 at89c51rd2/ed2 4235d?8051?12/03 ac parameters explanation of the ac symbols each timing symbol has 5 characters. the firs t character is always a ?t? (stands for time). the other characters, depending on their positions, stand for the name of a signal or the logical status of that signal. the fo llowing is a list of all the characters and what they stand for. example:t avll = time for address valid to ale low. t llpl = time for ale low to psen low. (load capacitance for port 0, ale and psen = 100 pf; load capacitance for all other outputs = 80 pf.) table 77 table 80, and table 83 give the description of each ac symbols. table 78, table 79, table 81 and table 84 gives the range for each ac parameter. table 78, table 79 and table 85 give the frequency derating formula of the ac parame- ter for each speed range description. to calculate each ac symbols. take the x value in the correponding column (-m or -l) and use this value in the formula. example: t lliu for -m and 20 mhz, standard clock. x = 35 ns t 50 ns t cciv = 4t - x = 165 ns external program memory characteristics table 77. symbol description symbol parameter t oscillator clock period t lhll ale pulse width t avll address valid to ale t llax address hold after ale t lliv ale to valid instruction in t llpl ale to psen t plph psen pulse width t pliv psen to valid instruction in t pxix input instruction hold after psen t pxiz input instruction float after psen t aviv address to valid instruction in t plaz psen low to address float
121 at89c51rd2/ed2 4235d?8051?12/03 table 78. ac parameters for a fix clock table 79. ac parameters for a variable clock symbol -m -l units min max min max t25 25 ns t lhll 35 35 ns t avll 55ns t llax 55ns t lliv n 65 65 ns t llpl 55ns t plph 50 50 ns t pliv 30 30 ns t pxix 00ns t pxiz 10 10 ns t aviv 80 80 ns t plaz 10 10 ns symbol type standard clock x2 clock x parameter for -m range x parameter for -l range units t lhll min 2 t - x t - x 15 15 ns t avll min t - x 0.5 t - x 20 20 ns t llax min t - x 0.5 t - x 20 20 ns t lliv max 4 t - x 2 t - x 35 35 ns t llpl min t - x 0.5 t - x 15 15 ns t plph min 3 t - x 1.5 t - x 25 25 ns t pliv max 3 t - x 1.5 t - x 45 45 ns t pxix min x x 0 0 ns t pxiz max t - x 0.5 t - x 15 15 ns t aviv max 5 t - x 2.5 t - x 45 45 ns t plaz max x x 10 10 ns
122 at89c51rd2/ed2 4235d?8051?12/03 external program memory read cycle external data memory characteristics table 80. symbol description t pliv tplaz ale psen port 0 port 2 a0-a7 a0-a7 instr in instr in instr in address or sfr-p2 address a8-a15 address a8-a15 12 t clcl t aviv t lhll t avll t lliv t llpl t plph t pxav t pxix t pxiz t llax symbol parameter t rlrh rd pulse width t wlwh wr pulse width t rldv rd to valid data in t rhdx data hold after rd t rhdz data float after rd t lldv ale to valid data in t avdv address to valid data in t llwl ale to wr or rd t avwl address to wr or rd t qvwx data valid to wr transition t qvwh data set-up to wr high t whqx data hold after wr t rlaz rd low to address float t whlh rd or wr high to ale high
123 at89c51rd2/ed2 4235d?8051?12/03 table 81. ac parameters for a fix clock symbol -m -l units min max min max t rlrh 125 125 ns t wlwh 125 125 ns t rldv 95 95 ns t rhdx 00ns t rhdz 25 25 ns t lldv 155 155 ns t av dv 160 160 ns t llwl 45 105 45 105 ns t avwl 70 70 ns t qvwx 55ns t qvwh 155 155 ns t whqx 10 10 ns t rlaz 00ns t whlh 5 45 5 45 ns table 82. ac parameters for a variable clock symbol type standard clock x2 clock x parameter for -m range x parameter for -l range units t rlrh min 6 t - x 3 t - x 25 25 ns t wlwh min 6 t - x 3 t - x 25 25 ns t rldv max 5 t - x 2.5 t - x 30 30 ns t rhdx min x x 0 0 ns t rhdz max 2 t - x t - x 25 25 ns t lldv max 8 t - x 4t -x 45 45 ns t avdv max 9 t - x 4.5 t - x 65 65 ns t llwl min 3 t - x 1.5 t - x 30 30 ns t llwl max 3 t + x 1.5 t + x 30 30 ns t avwl min 4 t - x 2 t - x 30 30 ns t qvwx min t - x 0.5 t - x 20 20 ns t qvwh min 7 t - x 3.5 t - x 20 20 ns t whqx min t - x 0.5 t - x 15 15 ns t rlaz max x x 0 0 ns t whlh min t - x 0.5 t - x 20 20 ns t whlh max t + x 0.5 t + x 20 20 ns
124 at89c51rd2/ed2 4235d?8051?12/03 external data memory write cycle external data memory read cycle serial port timing - shift register mode table 83. symbol description t qvwh t llax ale psen wr port 0 port 2 a0-a7 data out address or sfr-p2 t avwl t llwl t qvwx address a8-a15 or sfr p2 t whqx t whlh t wlwh ale psen rd port 0 port 2 a0-a7 data in address or sfr-p2 t avwl t llwl t rlaz address a8-a15 or sfr p2 t rhdz t whlh t rlrh t lldv t rhdx t llax t avdv symbol parameter t xlxl serial port clock cycle time t qvhx output data set-up to clock rising edge t xhqx output data hold after clock rising edge t xhdx input data hold after clock rising edge t xhdv clock rising edge to input data valid
125 at89c51rd2/ed2 4235d?8051?12/03 table 84. ac parameters for a fix clock table 85. ac parameters for a variable clock shift register timing waveforms external clock drive waveforms symbol -m -l units min max min max t xlxl 300 300 ns t qvhx 200 200 ns t xhqx 30 30 ns t xhdx 00ns t xhdv 117 117 ns symbol type standard clock x2 clock x parameter for -m range x parameter for -l range units t xlxl min 12 t 6 t ns t qvhx min 10 t - x 5 t - x 50 50 ns t xhqx min 2 t - x t - x 20 20 ns t xhdx min x x 0 0 ns t xhdv max 10 t - x 5 t- x 133 133 ns input data valid valid valid valid 0123456 8 7 ale clock output data write to sbuf clear ri t xlxl t qvxh t xhqx t xhdv t xhdx set ti set ri instruction 01234567 valid valid valid valid v cc -0.5v 0.45v 0.7v cc 0.2v cc -0.1 t chcl t clcx t clcl t clch t chcx
126 at89c51rd2/ed2 4235d?8051?12/03 ac testing input/output waveforms ac inputs during testing are driven at v cc - 0.5 for a logic ?1? and 0.45v for a logic ?0?. timing measurement are made at v ih min for a logic ?1? and v il max for a logic ?0?. float waveforms for timing purposes as port pin is no longer floating when a 100 mv change from load voltage occurs and begins to float when a 100 mv change from the loaded v oh /v ol level occurs. i ol /i oh 20 ma. clock waveforms valid in normal clock mode. in x2 mode xtal2 must be changed to xtal2/2. input/output 0.2 v cc + 0.9 0.2 v cc - 0.1 v cc -0.5v 0.45v float v oh - 0.1v v ol + 0.1v v load v load + 0.1v v load - 0.1v
127 at89c51rd2/ed2 4235d?8051?12/03 figure 56. internal clock signals this diagram indicates when signals are clocked internally. the time it takes the signals to propagate to the pins, however, ranges from 25 to 125 ns. this propagation delay is dependent on variables such as temperature and pin loading. propaga- tion also varies from output to output and component. typically though (t a = 25 c fully loaded) rd and wr propagation delays are approximately 50 ns. the other signals are typica lly 85 ns. propagation delays are incorporated in the ac specifications. data pcl out data pcl out data pcl out sampled sampled sampled state4 state5 state6 state1 state2 state3 state4 state5 p1 p2 p1 p2 p1 p2 p1 p2 p1 p2 p1 p2 p1 p2 p1 p2 float float float these signals are not activated during the execution of a movx instruction indicates address transitions external program memory fetch float data sampled dpl or rt out indicates dph or p2 sfr to pch transition pcl out (if program memory is external) pcl out (even if program memory is internal) pcl out (if program memory is externa l) old data new data p0 pins sampled p1, p2, p3 pins sampled p1, p2, p3 pins sampled p0 pins sampled rxd sampled internal clock xtal2 ale psen p0 p2 (ext) read cycle write cycle rd p0 p2 wr port operation mov port src mov dest p0 mov dest port (p1. p2. p3) (includes into. int1. to t1) serial port shift clock txd (mode 0) data out dpl or rt out indicates dph or p2 sfr to pch transition p0 p2 rxd sampled
128 at89c51rd2/ed2 4235d?8051?12/03 ordering information note: 1. for plcc68 and vqfp64 packages, please contact atmel sales office for availability. table 86. possible order entries part number data eeprom supply voltage temperature range package packing product marking at89c51rd2-slsim no 2.7v - 5.5v industrial plcc44 stick at89c51rd2-im at89c51rd2-rltim vqfp44 tray at89c51rd2-im at89c51rd2-rdtim (1) vqfp64 tray at89c51rd2-im at89c51rd2-smsim (1) plcc68 stick at89c51rd2-im AT89C51ED2-slsim yes plcc44 stick AT89C51ED2-im AT89C51ED2-rltim vqfp44 tray AT89C51ED2-im AT89C51ED2-3csim pdil40 stick AT89C51ED2-im AT89C51ED2- smsim plcc68 stick AT89C51ED2-im AT89C51ED2-rdtim vqfp64 tray AT89C51ED2-im
129 at89c51rd2/ed2 4235d?8051?12/03 packaging information plcc44
130 at89c51rd2/ed2 4235d?8051?12/03 vqfp44
131 at89c51rd2/ed2 4235d?8051?12/03 plcc68
132 at89c51rd2/ed2 4235d?8051?12/03 vqfp64
133 at89c51rd2/ed2 4235d?8051?12/03 pdil40
134 at89c51rd2/ed2 4235d?8051?12/03 datasheet change log for at89c51rd2/ed2 changes from 4235a - 04/03 to 4135b - 06/03 1. v ih min changed from 0.2 v cc + 1.1 to 0.2 v cc + 0.9. 2. added por/pfd and reset specific sections. 3. added dil40 package. 4. added flash write programming time specification. changes from 4235b - 06/03 to 4235c - 08/03 1. changed maximum frequency to 60 mhz in x1 mode and 30 mhz in x2 mode for vcc = 4.5v to 5.5v and internal code execution. 2. added pdil40 packaging for AT89C51ED2. changes from 4235c - 08/03 to 4235d - 12/03 1. improved explanations throughout the document.
i at89c51rd2/ed2 4235d?8051?12/03 table of contents features ................................................................................................. 1 description ............................................................................................ 1 block diagram ....................................................................................... 4 sfr mapping ......................................................................................... 5 pin configurations .............................................................................. 10 port types ........................................................................................... 15 oscillator ............................................................................................. 16 registers............................................................................................................. 16 functional block diagram ...................................................................................17 enhanced features ............................................................................. 18 x2 feature .......................................................................................................... 18 dual data pointer register (d ptr) ................................................... 22 expanded ram (xram) ..................................................................... 25 registers............................................................................................................. 27 reset .................................................................................................... 28 introduction ......................................................................................................... 28 reset input ......................................................................................................... 28 reset output .......................................................................................................29 power monitor ..................................................................................... 30 description.......................................................................................................... 30 timer 2 ................................................................................................. 32 auto-reload mode ............................................................................................... 32 programmable clock-output ................................................................................................................. 3 3 registers............................................................................................................. 35 programmable counter array (pca) ................................................ 37 pca capture mode............................................................................................. 45 16-bit software timer/ compare mode............................................................... 45 high speed output mode ................................................................................... 46 pulse width modulator mode.............................................................................. 47 pca watchdog timer ......................................................................................... 48
ii at89c51rd2/ed2 4235d?8051?12/03 serial i/o port ...................................................................................... 50 framing error detection ..................................................................................... 50 automatic address recognition.......................................................................... 51 registers............................................................................................................. 53 baud rate selection for uart for mode 1 and 3............................................... 53 uart registers.................................................................................................. 56 keyboard interface ............................................................................. 61 registers............................................................................................................. 62 serial port interface (spi) ................................................................... 65 features.............................................................................................................. 65 signal description............................................................................................... 65 functional description ........................................................................................ 67 interrupt system ................................................................................. 74 registers............................................................................................................. 75 interrupt sources and vector addresses............................................................ 76 power management ............................................................................ 83 introduction ......................................................................................................... 83 idle mode ............................................................................................................ 83 power-down mode ............................................................................................. 83 registers............................................................................................................. 86 hardware watchdog timer ................................................................ 87 using the wdt ................................................................................................... 87 wdt during power-down and idle...................................................................... 88 once ? mode (on- chip emulati on) .................................................. 89 power-off flag ..................................................................................... 90 reduced emi mode ............................................................................. 91 eeprom data memory ....................................................................... 92 write data........................................................................................................... 92 read data........................................................................................................... 94 registers............................................................................................................. 95 flash/eeprom memory ..................................................................... 96 features.............................................................................................................. 96 flash programming and erasure........................................................................ 96 flash registers and memory map...................................................................... 97 flash memory status........................................................................................ 100 memory organization ....................................................................................... 100
iii at89c51rd2/ed2 4235d?8051?12/03 bootloader architecture .................................................................................... 101 isp protocol description ...................................................................................105 functional description ...................................................................................... 106 flow description ............................................................................................... 107 api call description.......................................................................................... 115 electrical characteristics ................................................................. 117 absolute maximum ratings ..............................................................................117 dc parameters for standard voltage ...............................................................117 ac parameters ................................................................................................. 120 ordering information ........................................................................ 128 packaging information ..................................................................... 129 plcc44 ............................................................................................................ 129 vqfp44 ............................................................................................................ 130 dil40 ................................................................................................................ 131 plcc68 ............................................................................................................ 132 vqfp64 ............................................................................................................ 133 pdil40.............................................................................................................. 134 datasheet change log for at89c51rd2/ed2 ............................... 135 changes from 4235a -04/03 to 4135b - 06/03 ................................................. 135 changes from 4235b -06/03 to 4235c - 08/03................................................. 135 changes from 4235c - 08/03 to 4235d - 12/03................................................ 135 table of contents .................................................................................. i
printed on recycled paper. disclaimer: atmel corporation makes no warranty for the use of its products , other than those expressly contained in the company?s standar d warranty which is detailed in atmel?s terms and conditions locate d on the company?s web site. the company assumes no responsibi lity for any errors which may appear in this document, reserves the right to change devices or specifications detailed herein at any time wi thout notice, and does not make any commitment to update the information contained herein. no licenses to patents or other intellectual property of atmel are granted by the company in connection with the sale of atmel produc ts, expressly or by implicati on. atmel?s products are not aut horized for use as critical components in life support devices or systems. atmel corporation atmel operations 2325 orchard parkway san jose, ca 95131, usa tel: 1(408) 441-0311 fax: 1(408) 487-2600 regional headquarters europe atmel sarl route des arsenaux 41 case postale 80 ch-1705 fribourg switzerland tel: (41) 26-426-5555 fax: (41) 26-426-5500 asia room 1219 chinachem golden plaza 77 mody road tsimshatsui east kowloon hong kong tel: (852) 2721-9778 fax: (852) 2722-1369 japan 9f, tonetsu shinkawa bldg. 1-24-8 shinkawa chuo-ku, tokyo 104-0033 japan tel: (81) 3-3523-3551 fax: (81) 3-3523-7581 memory 2325 orchard parkway san jose, ca 95131, usa tel: 1(408) 441-0311 fax: 1(408) 436-4314 microcontrollers 2325 orchard parkway san jose, ca 95131, usa tel: 1(408) 441-0311 fax: 1(408) 436-4314 la chantrerie bp 70602 44306 nantes cedex 3, france tel: (33) 2-40-18-18-18 fax: (33) 2-40-18-19-60 asic/assp/smart cards zone industrielle 13106 rousset cedex, france tel: (33) 4-42-53-60-00 fax: (33) 4-42-53-60-01 1150 east cheyenne mtn. blvd. colorado springs, co 80906, usa tel: 1(719) 576-3300 fax: 1(719) 540-1759 scottish enterprise technology park maxwell building east kilbride g75 0qr, scotland tel: (44) 1355-803-000 fax: (44) 1355-242-743 rf/automotive theresienstrasse 2 postfach 3535 74025 heilbronn, germany tel: (49) 71-31-67-0 fax: (49) 71-31-67-2340 1150 east cheyenne mtn. blvd. colorado springs, co 80906, usa tel: 1(719) 576-3300 fax: 1(719) 540-1759 biometrics/imaging/hi-rel mpu/ high speed converters/rf datacom avenue de rochepleine bp 123 38521 saint-egreve cedex, france tel: (33) 4-76-58-30-00 fax: (33) 4-76-58-34-80 literature requests www.atmel.com/literature 4235d?8051?12/03 ? atmel corporation 2003 . all rights reserved. atmel ? and combinations thereof are the trademarks of atmel corporation or its subsidiaries. other terms and product names may be the trademarks of others.

▲Up To Search▲

Price & Availability of AT89C51ED2

	To Download AT89C51ED2 Datasheet File
If you can't view the Datasheet, Please click here to try to view without PDF Reader .