rev. 2.2 _30 seiko instruments inc. 1 the s-24c0xa is a series of 2-wired, low power 1k/2k/4k-bit eeproms with a wide operating range. they are organized as 128-word 8-bit, 256-word 8-bit, and 512-word 8-bit, respectively. each is capable of page write, and sequential read. the time for byte write and page write is the same, i. e., 1 msec. (max.) during operation at 5 v 10%. �? package �y 8-pin dip (pkg drawing code : dp008-a,dp008-c) �y 8-pin sop (pkg drawing code : fj008-d,fj008-e) �? pin assignment figure 1 �? pin functions pin number name dip sop function a0 11 address input (no connection in the s-24c04a*) a1 22 address input a2 33 address input gnd 44 ground sda 55 serial data input/output scl 66 serial clock input test/wp 77 test pin (s-24c01a): connected to gnd. wp (write protection) pin (s-24c02a, s-24c04a): * connected to vcc: protection valid * connected to gnd: protection invalid vcc 88 power supply cmos 2-wire serial eeprom s-24c01a/02a/04a ? endurance: 10 6 cycles/word ? data retention: 10 years ? write protection: s-24c02a, s-24c04a ? s-24c01a: 1 kbits ? s-24c02a: 2 kbits ? s-24c04a: 4 kbits �? features ? low power consumption standby: 1.0 a max. (v cc =5.5 v) operating: 0.4 ma max. (v cc =5.5 v) 0.3 ma max. (v cc =3.3 v) ? wide operating voltage range write: 2.5 to 5.5 v read: 1.8 to 5.5 v ? page write 8 bytes (s-24c01a, s-24c02a) 16 b y tes ( s-24c04a ) 8-pin dip top view vcc gnd scl a1 a2 sda a0 1 2 3 4 5 6 7 8 test/wp 8-pin sop top view a0 a1 a2 gnd 6 5 8 7 3 4 1 2 test/wp vcc scl sda s-24c01adpx-uu s-24c02adpx-uu s-24c04adpx-uu s-24c01afja-zz-uuw s-24c02afja-zz-uuw s-24c04afja-zz-uuw * lower-case letters x, uu, zz and w differ depending on the packing form. see �? ordering information and �? dimensions. * when in use, connect to gnd or vcc. table 1 discontinued product
cmos 2-wire serial eeprom s-24c01a/02a/04a rev. 2.2 _30 2 seiko instruments inc. �? block diagram �? absolute maximum ratings parameter symbol ratings unit power supply voltage v cc -0.3 to +7.0 v input voltage v in -0.3 to v cc +0.3 v output voltage v out -0.3 to v cc v storage temperature under bias t bias -50 to +95 c storage temperature t stg -65 to +150 c fi g ure 2 v cc gnd serial clock controller device address comparator address counter y decoder data output ack output controller high-voltage generator start/stop detector data register eeprom x decoder selector scl sda a2 a1 a0 d in d out r / w load inc comp load test/wp* * s-24c02a or s-24c04a table 2 discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 3 �? recommended operating conditions table 3 parameter symbol conditions min. typ. max. unit read operation 1.8 ? 5.5 v power supply voltage v cc write operation 2.5 ? 5.5 v v cc =2.5 to 5.5v 0.7 v cc ?v cc v high level input voltage v ih v cc =1.8 to 2.5v 0.8 v cc ?v cc v v cc =2.5 to 5.5v 0.0 ? 0.3 v cc v low level input voltage v il v cc =1.8 to 2.5v 0.0 ? 0.2 v cc v operating temperature t opr ? -40 ? +85 c �? pin capacitance table 4 (ta=25c, f=1.0 mhz, v cc =5 v) parameter symbol conditions min. typ. max. unit input capacitance c in v in =0 v (scl, a0, a1, a2, wp) ? ? 10 pf input/output capacitance c i / o v i / o =0 v (sda) ? ? 10 pf �? endurance table 5 parameter symbol min. typ. max. unit endurance n w 10 6 ? ? cycles/word discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 4 seiko instruments inc. �? dc electrical characteristics table 6 v cc =4.5 v to 5.5 vv cc =2.5 to 4.5 vv cc =1.8 to 2.5 v parameter symbol conditions min. typ. max. min. typ. max. min. typ. max. unit current consumption (read) i cc1 f=100 khz ?? 0.4 ?? 0.3 ?? 0.2 ma current consumption (program) i cc2 f=100 khz ?? 2.0 ?? 1.5 ??? ma table 7 v cc =4.5 v to 5.5 v v cc =2.5 to 4.5 v v cc =1.8 to 2.5 v parameter symbol conditions min. typ. max. min. typ. max. min. typ. max. unit standby current consumption i sb v in =v cc or gnd ?? 1.0 ?? 0.6 ?? 0.4 a input leakage current i li v in =gnd to v cc ? 0.1 1.0 ? 0.1 1.0 ? 0.1 1.0 a output leakage current i lo v out =gnd to v cc ? 0.1 1.0 ? 0.1 1.0 ? 0.1 1.0 a i ol =3.2 ma ?? 0.4 ?? 0.4 ??? v i ol =1.5 ma ?? 0.3 ?? 0.3 ?? 0.5 v low level output voltage v ol i ol =100 a ?? 0.1 ?? 0.1 ?? 0.1 v current address retention voltage v ah ? 1.5 ? 5.5 1.5 ? 4.5 1.5 ? 2.5 v discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 5 �? ac electrical characteristics table 9 v cc =1.8v to 5.5v parameter symbol min. typ. max. unit scl clock frequency f scl 0 ? 100 khz scl clock time "l" t low 4.7 ?? s scl clock time"h" t high 4.0 ?? s sda output delay time t aa 0.3 ? 3.5 s sda output hold time t dh 0.3 ?? s start condition setup time t su.sta 4.7 ?? s start condition hold time t hd.sta 4.0 ?? s data input setup time t su.dat 50 ?? ns data input hold time t hd.dat 0 ?? ns stop condition setup time t su.sto 4.7 ?? s scl sda rising time t r ?? 1.0 s scl sda falling time t f ?? 0.3 s bus release time t buf 4.7 ?? s noise suppression time t i ?? 100 ns input pulse voltage 0.1 v cc to 0.9 v cc input pulse rising/falling time 20 ns output judgment voltage 0.5 v cc output load 100 pf+ pullup resistance 1.0 k ? table 8 measurement conditions v cc r=1.0k sda c=100pf fi g ure 3 output load circuit figure 4 bus timing scl sda in sda out t buf t r t su.sto t su.dat t hd.dat t dh t aa t high t low t hd.sta t su.sta t f invalid valid discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 6 seiko instruments inc. table 10 v cc =4.5 to 5.5v v cc =2.5 to 4.5v item symbol min. typ. max. min. typ. max. unit write time t wr ? 0.8 1.0 ? 4.0 5.0 ms �? pin functions 1. address input pins (a0, a1, and a2) connect pins a0, a1, and a2 to the gnd or the v cc , respectively, to assign slave addresses. there are 8 different ways to assign slave addresses in the s-24c01a and s-24c02a through a combination of pins a0, a1, and a2, and 4 ways to assign them in the s-24c04a through a combination of pins a1 and a2. when the input slave address coincides with the slave address transmitted from the master device, 1 device can be selected from among multiple devices connected to the bus. always connect the address input pin to gnd or v cc and leave it unchanged. 2. sda (serial data input/output) pin the sda pin is used for bilateral transmission of serial data. it consists of a signal input pin and an nch open-drain transistor output pin. usually pull up the sda line via resistance to the v cc , and use it with other open-drain or open-collector output devices connected in a wired or configuration. 3. scl (serial clock input) pin the scl pin is used for serial clock input. it is capable of processing signals at the rising and falling edges of the scl clock input signal. make sure the rising time and falling time conform to the specifications. 4. test/wp pin the s-24c01a does not have a write protection (wp) function. the pin serves as a test pin and shoud always be connect to the gnd. in the s-24c02a and s-24c04a, this pin is used for write protection. when there is no need for write protection, connect the pin to the gnd; when there is a need for write protection, connect the pin to the vcc. figure 5 write cycle scl sda d0 write data acknowledge stop condition start condition t wr discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 7 �? operation 1. start condition when the scl line is "h," the sda line changes from "h" to "l." this allows the device to go to the start condition. all operations begin from the start condition. 2. stop condition when the scl line is "h," the sda line changes from "l" to "h." this allows the device to go to the stop condition. when the device receives the stop condition signal during a read sequence, the read operation is interrupted, and the device goes to standby mode. when the device receives the stop condition signal during write sequence, the retrieval of write data is halted, and the eeprom initiates rewrite . 3. data transmission changing the sda line while the scl line is "l" allows the data to be transmitted. a start or stop condition is recognized when the sda line changes while the scl line is "h." figure 6 start/stop conditions t su.sta t hd.sta t su.sto start condition stop condition scl sda figure 7 data transmission timing t su.dat t hd.dat scl sda discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 8 seiko instruments inc. 4. acknowledgment the unit of data transmission is 8 bits. by turning the sda line "l," the slave device mounted on the system bus which receives the data during the 9th clock cycle outputs the acknowledgment signal verifying the data reception. when the eeprom is rewriting, the device does not output the acknowledgment signal. 5. device addressing to perform data communications, the master device mounted on the system outputs the start condition signal to the slave device. next, the master device outputs 7-bit length device address and a 1-bit length read/write instruction code onto the sda bus. upper 4 bits of the device address are called the "device code," and set to "1010." successive 3 bits are called the "slave address." it is used to select a device on the system bus, and compared to the predetermined address value at the address input pin (a2, a1, or a0). when the comparison results match, the slave device outputs the acknowledgment signal during the 9th clock cycle . in the s-24c04a, "a0" does not exist in the slave addresses. so, "a0" becomes "p0." "p0" is a page address bit and is equivalent to an additional uppermost bit of the word address. accordingly, when p0="0," the former half area corresponding to 2 kbits (addresses from 000h to 0ffh) in the entire memory are selected; when p0="1," the latter half area corresponding to 2 kbits (addresses from 100h to 1ffh) in all areas of the memory are selected. figure 8 acknowledgment output timing 1 8 9 acknow- ledgment output t aa t dh start condition scl (eeprom input) sda (master output) sda (eeprom output) figure 9 device address slave address 1 0 1 0 a2 a1 a0 r/w device code s-24c01a s-24c02a msb lsb 1 0 1 0 a2 a1 a0 r/w 1 0 1 0 a2 a1 p0 r/w s-24c04a msb lsb device code slave address page a ddress discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 9 6. write 6.1 byte write when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "0," following the start condition signal, it outputs the acknowledgment signal. next, when the eeprom receives an 8-bit length word address, it outputs the acknowledgment signal. after the eeprom receives 8-bit write data and outputs the acknowledgment signal, it receives the stop condition signal. next, the eeprom at the specified memory address starts to rewrite. when the eeprom is rewriting, all operations are prohibited and the acknowledgment signal is not output. 6.2 page write up to 8 bytes per page can be written in the s-24c01a and s-24c02a. up to 16 bytes per page can be written in the s-24c04a. basic data transmission procedures are the same as those in the "byte write." however, when the eeprom receives 8-bit write data which corresponds to the page size, the page can be written. when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "0," following the start condition signal, it outputs the acknowledgment signal. when the eeprom receives an 8-bit length word address, it outputs the acknowledgment signal. after the eeprom receives 8-bit write data and outputs the acknowledgment signal, it receives 8- bit write data corresponding to the next word address, and outputs the acknowledgment signal. the eeprom repeats reception of 8-bit write data and output of the acknowledgment signal in succession. it is capable of receiving write data corresponding to the maximum page size. when the eeprom receives the stop condition signal, it starts to rewrite, corresponding to the size of the page, on which write data, starting from the specified memory address, is received. figure 10 byte write s t a r t 1 0 1 0 w r i t e s t o p device addres word address data r / w m s b sda adr inc (address increment) a2 a1 a0 w7 w6 w5 w4 w3 w2 w1 w0 d7 d6 d5 d4 d3 d2 d1 d0 a c k l s b a c k a c k 0 w7 is optional in the s-24c01a. a0 is p0 in the s-24c04a. discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 10 seiko instruments inc. s t a r t 1 0 1 0 w r i t e s t o p device addres word address (n) data (n) r / w m s b sda line adr inc a2 a1 a0 w7 w6 w5 w4 w3 w2 w1 w0 d7 d6 d5 d4 d3 d2 d1 d0 a c k l s b a c k a c k 0 d7 d0 d7 d0 adr inc a c k adr inc a c k data (n+1) data (n+x) w7 is optional in the s-24c01a. a0 is p0 in the s-24c04a. in the s-24c01a or s-24c02a, the lower 3 bits of the word address are automatically incremented each when the eeprom receives 8-bit write data. even if the write data exceeds 8 bytes, the upper 5 bits at the word address remain unchanged, the lower 3 bits are rolled over and overwritten. in the s-24c04a, the lower 4 bits at the word address are automatically incremented each when the eeprom receives 8 bit write data. even when the write data exceeds 16 bytes, the upper 4 bits of the word address and page address p0 remain unchanged, and the lower 4 bits are rolled over and overwritten. 6.3 acknowledgment polling acknowledgment polling is used to know when the rewriting of the eeprom is finished. after the eeprom receives the stop condition signal and once it starts to rewrite, all operations are prohibited. also, the eeprom cannot respond to the signal transmitted by the master device. accordingly, the master device transmits the start condition signal and the device address read/write instruction code to the eeprom (namely, the slave device) to detect the response of the slave device. this allows users to know when the rewriting of the eeprom is finished. that is, if the slave device does not output the acknowledgment signal, it means that the eeprom is rewriting; when the slave device outputs the acknowledgment signal, you can know that rewriting has been completed. it is recommended to use read instruction "1" for the read/write instruction code transmitted by the master device. 6.4 write protection the s-24c02a and the s-24c04a are capable of protecting the memory. when the wp pin is connected to v cc , writing to 50% of the latter half of all memory area (080h to 0ffh in the s-24c02a; 100h to 1ffh in the s-24c04a) is prohibited. even when writing is prohibited, since the controller inside the ic is operating, the response to the signal transmitted by the master device is not available during the time of writing (t wr ). when the wp pin is connected to gnd, the write protection becomes invalid, and writing in all memory area becomes available. however, when there is no need for using write protection, always connect the wp pin to gnd. figure 11 page write discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 11 7. read 7.1 current address read the eeprom is capable of storing the last accessed memory address during both writing and reading. the memory address is stored as long as the power voltage is more than the retention voltage v ah . accordingly, when the master device recognizes the position of the address pointer inside the eeprom, data can be read from the memory address of the current address pointer without assigning a word address. this is called "current address read." "current address read" is explained for when the address counter inside the eeprom is an "n" address. when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "1," following the start condition signal, it outputs the acknowledgment signal. however, in the s- 24c04a, page address p0 becomes invalid, and the memory address of the current address pointer becomes valid. next, 8-bit length data at an "n" address is output from the eeprom, in synchronization with the scl clock. the address counter is incremented at the falling edge of the scl clock by which the 8th bit of data is output, and the address counter goes to address n+1. the master device does not output the acknowledgment signal and transmits the stop condition signal to finish reading. for recognition of the address pointer inside the eeprom, take into consideration the following: the memory address counter inside the eeprom is automatically incremented for every falling edge of the scl clock by which the 8th bit of data is output during the time of reading. during the time of writing, upper bits of the memory address (upper 5 bits of the word address in the s-24c01a and s-24c02a; upper 4 bits of the word address and page address p0 in the s-24c04a) are left unchanged and are not incremented. figure 12 current address read s t a r t 1 0 1 0 r e a d s t o p device address r / w m s b sda line adr inc a2 a1 a0 d7 d6 d5 d4 d3 d2 d1 d0 a c k l s b 1 data no ack from master device (a0 is p0 in the s-24c04a) discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 12 seiko instruments inc. 7.2 random read random read is a mode used when the data is read from arbitrary memory addresses. to load a memory address into the address counter inside the eeprom, first perform a dummy write according to the following procedures: when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "0," following the start condition signal, it outputs the acknowledgment signal. next, the eeprom receives an 8-bit length word address and outputs the acknowledgment signal. last, the memory address is loaded into the address counter of the eeprom. the eeprom receives the write data during byte or page writing. however, data reception is not performed during dummy write. the memory address is loaded into the memory address counter inside the eeprom during dummy write. after that, the master device can read the data starting from the arbitrary memory address by transmitting a new start condition signal and performing the same operation as that in the "current read." that is, when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "1," following the start condition signal, it outputs the acknowledgment signal. next, 8-bit length data is output from the eeprom, in synchronization with the scl clock. the master device does not output an acknowledgment signal and transmits the stop condition signal to finish reading. s t a r t 1 0 1 0 w r i t e s t o p device address word address (n) r / w m s b sda line a2 a1 a0 w7 w6 w5 w4 w3 w2 w1 w0 a c k l s b a c k a c k 0 1 0 1 0 a2 a1 a0 1 d7 d6 d5 d4 d3 d2 d1 d0 data (n) dummy write device address r e a d no ack from master device adr inc s t a r t w7 is optional in the s-24c01a. a0 is p0 in the s-24c04a. figure 13 random read discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 13 7.3 sequential read when the eeprom receives a 7-bit length device address and a 1-bit read/write instruction code "1" in both current and random read operations, following the start condition signal, it outputs the acknowledgment signal when 8-bit length data is output from the eeprom, in synchronization with the scl clock, the memory address counter inside the eeprom is automatically incremented at the falling edge of the scl clock, by which the 8th data is output. when the master device transmits the acknowledgment signal, the next memory address data is output. when the master device transmits the acknowledgment signal, the memory address counter inside the eeprom is incremented and read data in succession. this is called "sequential read." when the master device does not output an acknowledgement signal and transmits the stop condition signal, the read operation is finished. data can be read in the "sequential read" mode in succession. when the memory address counter reaches the last word address, it rolls over to the first memory address. figure 14 sequential read r e a d s t o p device addres r / w adr inc d7 d0 a c k a c k a c k 1 d7 d0 adr inc a c k adr inc sda line data (n) d7 d0 d7 d0 data (n+1) data (n+2) data (n+x) no ack from master device adr inc discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 14 seiko instruments inc. 8. address increment timing the address increment timing is as follows. see figures 15 and 16. during reading operation, the memory address counter is automatically incremented at the falling edge of the scl clock (the 8th read data is output). during writing operation, the memory address counter is also automatically incremented at the falling edge of the scl clock when the 8th bit write data is fetched. figure 15 address increment timing during reading scl sda r / w=1 address increment 891 89 d7 output d0 output ack output figure 16 address increment timing during writing scl sda r / w=0 891 89 d7 input d0 input ack output ack output address increment purchase of i 2 c components of seiko instruments inc. conveys a license under the philips i 2 c patent rights to use these components in an i 2 c system, provided that the system conforms to the i 2 c standard specification as defined by philips. please note that any product or system incorporating this ic may infringe upon the philips i 2 c bus patent rights depending upon its configuration. in the event that such product or system incorporating the i 2 c bus infringes upon the philips paten t rights, seiko instruments inc. shall not bear any responsibility for any matters with regard to and arising from such patent infringement. discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 15 �? ordering information s-24c0xa yyy - zz - uuw p code (distincion for package process) none s 1a endurance code 11 : 10 6 cycles taping specification none for dip and sop in magazine tb package code dp : dip dpa : dip fja : sop product name s-24c01a : 1k bits s-24c02a : 2k bits s-24c04a : 4k bits ordering names for dip product name package code taping specification endurance code p code package/tape/reel drawings dp none none ? 1a dp008-c s-24c01a s-24c02a s-24c04a dpa none ? 11 none dp008-a note the endurarance of s-24c0xadp-1a is 10 6 cycles, though the ordering name does not have the endurance code. ordering names for sop product name package code taping specification endurance code p code package/tape/reel drawings s-24c01a fja ? tb (none for magazine) ? 11 none fj008-d none fj008-d s-24c02a fja ? tb (none for magazine) ? 11 s fj008-d fj008-e s-24c04a fja ? tb (none for magazine) ? 11 none fj008-d note 1) package dimensions of sops whose package code is fja are the same in the range of deviation. 2) please contact an sii local office or a local representative for details. discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 16 seiko instruments inc. �? characteristics 1. dc characteristics 1.1 current consumption (read) i cc1 ? ambient temperature ta 1.2 current consumption (read) i cc1 ? ambient temperature ta 1.3 current consumption (read) i cc1 ? ambient temperature ta 1.4 current consumption (read) i cc1 ? power supply voltage v cc 1.5 current consumption (read) i cc1 ? power supply voltage v cc 1.6 current consumption (read) i cc1 ? clock frequency fscl 1.7 current consumption (program) i cc2 ? ambient temperature ta 1.8 current consumption (program) i cc2 ? ambient temperature ta ta (c) 200 100 v cc =5.5 v fscl=100 khz data=0101 0 -40 0 85 i cc1 ( a) ta (c) 200 100 v cc =3.3 v fscl=100 khz data=0101 0 -40 0 85 i cc1 ( a) ta (c) 40 20 v cc =1.8 v fscl=100 khz data=0101 0 -40 0 85 i cc1 ( a) 100 50 0 234567 ta=25c fscl=100 khz data=0101 v cc (v) i cc1 ( a) 100 50 0 23456 7 ta=25c fscl=400 khz data=0101 v cc (v) 100 50 0 i cc1 ( a) v cc =5.0 v ta=25c 100k 200k fscl(hz) i cc1 ( a) 300k 400k ta (c) 1.0 0.5 v cc =5.5 v 0 -40 0 85 i cc2 ( ma ) ta (c) 1.0 0.5 v cc =3.3 v 0 -40 0 85 i cc2 ( ma ) discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 17 1.10 current consumption (program) i cc2 ? power supply voltage v cc 1.11 standby current consumption i sb ? ambient temperature ta 1.12 input leakage current i li ? ambient temperature ta 1.13 input leakage current i li ? ambient temperature ta 1.14 output leakage current i lo ? ambient temperature ta 1.15 output leakage current i lo ? ambient temperature ta 1.9 current consumption (program) i cc2 ? ambient temperature ta ta (c) 1.0 0.5 v cc =2.5 v 0 -40 0 85 i cc2 ( ma ) 1.0 0.5 0 23456 7 ta=25c v cc (v) i cc2 ( ma ) 10 -6 10 -7 10 -8 10 -9 10 -10 v cc =5.5 v 10 -11 ta (c) -40 0 85 ta (c) 1.0 0.5 v cc =5.5 v a0, a1, a2, sda scl,test/wp=0v 0 -40 0 85 i li ( a) i sb ( a ) ta (c) 1.0 0.5 v cc =5.5 v sda=0v 0 -40 0 85 i lo ( a) ta (c) 1.0 0.5 0 -40 0 85 v cc =5.5 v a0, a1, a2, sda scl, test/wp=5.5v i li ( a) ta (c) 1.0 0.5 v cc =5.5 v sda=5.5 v 0 -40 0 85 i lo ( a) discontinued product
cmos 2-wired serial eeprom s-24c01a/02a/04a rev. 2.2 _30 18 seiko instruments inc. 1.20 high input inversion voltage vih ? power supply voltagev cc 1.16 low level output voltage v ol ? ambient tem p erature ta 1.17 low level output voltage v ol ? ambient tem p erature ta 1.18 low level output current i ol ? ambient temperature ta 1.19 low level output current i ol ? ambient temperature ta 1.21 high input inversion voltage vih ? ambient temperature ta 1.22 low input inversion voltage vil ? power supply voltagev cc 1.23 low input inversion voltage vil ? ambient temperature ta ta (c) 0.3 0.2 v cc =4.5 v i ol =2.3 ma -40 0 85 v ol ( v ) 0.1 ta (c) 0.03 0.02 v cc =1.8 v i ol =100 a -40 0 85 v ol ( v ) 0.01 ta (c) 20 10 v cc =4.5 v v ol =0.45 v 0 -40 0 85 i ol ( ma ) ta (c) 1.0 0.5 v cc =1.8 v v ol =0.1 v 0 -40 0 85 i ol ( ma ) ta=25c a0, a1, a2, sda scl, test/wp 1.0 0 2.0 3.0 vih (v) 1 234567 v cc (v) v cc =5.0 v a0, a1, a2, sda scl, test/wp 1.0 0 2.0 3.0 vih (v) ta (c) -40 085 ta=25c a0, a1, a2, sda scl, test/wp 1.0 0 2.0 3.0 vil (v) 1234567 v cc (v) 1.0 0 2.0 3.0 vil (v) ta (c) -40 085 ta=5.0v a0, a1, a2, sda scl, test/wp discontinued product
cmos 2-wire serial eeprom rev. 2.2 _30 s-24c01a/02a/04a seiko instruments inc. 19 2. ac characteristics 2.1 maximum operating frequency fmax ? power supply voltage v cc 2.2 write time t wr ? power supply voltage v cc 2.3 write time t wr ? ambient temperature ta 2.4 write time t wr ? ambient temperature ta 2.5 sda output delay time t pd ? ambient temperature ta 2.6 sda output delay time t pd ? ambient temperature ta 2.7 data output delay time t pd ? ambient temperature ta 10k 234 5 ta=25c v cc (v) f max (hz) 1 4 2 23456 7 ta=25c v cc (v) t wr (ms) 1 100k 1m 1 3 ta ( c) 1.5 1.0 v cc =4.5 v -40 0 85 0.5 t wr ( ms ) ta (c) 4 3 v cc =2.5 v -40 0 85 2 t wr ( ms ) ta (c) 1.5 1.0 v cc =4.5 v -40 0 85 0.5 t pd ( s) ta (c) 1.5 1.0 v cc =2.7 v -40 0 85 0.5 t pd ( s) ta (c) 3.0 2.0 v cc =1.8 v -40 0 85 1.0 t pd ( s) discontinued product
�������� �������������� �� � � � �
� � � �� � � � � ������ �
�� � ��� �� � �� �
�� ����� �� ��������������� � � ����� ��
� �� !��� � ����
��
discontinued product
� ����������� ��
���
� � ��
�������� ��
���
� � �����
���
� � �����
���� ���������� �
���
�
��
��
�
�
���
�����������������������
���
� �
���
�
���
� �
���
�
����
�
��
�
���
�
!�
�"#����$�%�&$�� � !�
���"#����$�'�&$��
� �
���
�
�
� � �
!�
���"#����(�)�&$�
�
� ��
�
���
�
� � � *+ "��,�,�-������ ��
��
��
��� ��
�����
� ���
� .��,��/���-� �������
0-��� ������� � ������� �������� 1 discontinued product
� � � � �� ���
���
���� � ����������� ��
���
� � ��
�������� ��
���
� � �����
���
� � �����
���� �������
������ ����
�
�� ����
�
������� ����
���������� !���� "��# "��� ��$%���� ���%��� ���%��� #��%��� ���%���� &��� ���� &��� ���� �'�()� ���%���*��
���
+��
�
���(�
����%���, ����%��� � � � � ���%���� ���- ����%���� ����
������.�/� !���� ����
������.�0� !���� �%��� "�$ "�������� &��� ���� ���� ���� &��# ���� &��# ���� 1�� ��2
��� discontinued product
the information described herein is subject to change without notice. seiko instruments inc. is not responsible for any problems caused by circuits or diagrams described herein whose related industrial properties, patents, or other rights belong to third parties. the application circuit examples explain typical applications of the products, and do not guarantee the success of any specific mass-production design. when the products described herein are regulated products subject to the wassenaar arrangement or other agreements, they may not be exported without authorization from the appropriate governmental authority. use of the information described herein for other purposes and/or reproduction or copying without the express permission of seiko instruments inc. is strictly prohibited. the products described herein cannot be used as part of any device or equipment affecting the human body, such as exercise equipment, medical equipment, security systems, gas equipment, or any apparatus installed in airplanes and other vehicles, without prior written permission of seiko instruments inc. although seiko instruments inc. exerts the greatest possible effort to ensure high quality and reliability, the failure or malfunction of semiconductor products may occur. the user of these products should therefore give thorough consideration to safety design, including redundancy, fire-prevention measures, and malfunction prevention, to prevent any accidents, fires, or community damage that may ensue. discontinued product
|
