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| cy14v104la cy14v104na 4-mbit (512 k 8 / 256 k 16) nvsram cypress semiconductor corporation ? 198 champion court ? san jose , ca 95134-1709 ? 408-943-2600 document number: 001-53954 rev. *g revised july 24, 2013 4-mbit (512 k 8 / 256 k 16) nvsram features 25 ns and 45 ns access times internally organized as 512 k 8 (cy14v104la) or 256 k 16 (cy14v104na) hands off automatic store on power-down with only a small capacitor store to quantumtrap non-volatile elements initiated by software, device pin, or autostore on power-down recall to sram initiated by software or power-up infinite read, write, and recall cycles 1-million store cycles to quantumtrap 20 year data retention core v cc = 3.0 v to 3.6 v; io v ccq = 1.65 v to 1.95 v industrial temperature 48-ball fine-pitch ball grid array (fbga) package pb-free and restriction of hazardous substances (rohs) compliance functional description the cypress cy14v104la/cy14v104na is a fast static ram, with a non-volatile element in each memory cell. the memory is organized as 512 k bytes of 8 bits each or 256 k words of 16 bits each. the embedded non-volatile elements incorporate quantumtrap technology, producing the world?s most reliable non-volatile memory. the sram provides infinite read and write cycles, while independent non-volatile data resides in the highly reliable quantumtrap cell. data transfers from the sram to the non-volatile elements (the store operation) takes place automatically at power-down. on power-up, data is restored to the sram (the recall operat ion) from the non-volatile memory. both the store and recall operations are also available under software control. static ram array 2048 x 2048 r o w d e c o d e r column i/o column dec i n p u t b u f f e r s power control store/recall control quatrum trap 2048 x 2048 store recall v cc v cap hsb a 9 a 10 a 11 a 12 a 13 a 14 a 15 a 16 software detect a 14 - a 2 oe ce we bhe ble a 0 a 1 a 2 a 3 a 4 a 5 a 6 a 7 a 8 a 17 a 18 dq 0 dq 1 dq 2 dq 3 dq 4 dq 5 dq 6 dq 7 dq 8 dq 9 dq 10 dq 11 dq 12 dq 13 dq 14 dq 15 v ccq logic block diagram [1, 2, 3] notes 1. address a 0 ?a 18 for 8 configuration and address a 0 ?a 17 for 16 configuration. 2. data dq 0 ?dq 7 for 8 configuration and data dq 0 ?dq 15 for 16 configuration. 3. bhe and ble are applicable for 16 configuration only.
cy14v104la cy14v104na document number: 001-53954 rev. *g page 2 of 23 contents pinouts .............................................................................. 3 pin definitions .................................................................. 3 device operation .............................................................. 4 sram read ................................................................ 4 sram write ................................................................. 4 autostore operation .................................................... 4 hardware store operation ....................................... 4 hardware recall (power-up) .................................. 5 software store ......................................................... 5 software recall ....................................................... 5 preventing autostore .................................................. 6 data protection ............................................................ 6 maximum ratings ............................................................. 7 operating range ............................................................... 7 dc electrical characteristics .......................................... 7 data retention and endurance ....................................... 8 capacitance ...................................................................... 8 thermal resistance .......................................................... 8 ac test loads .................................................................. 9 ac test conditions .......................................................... 9 ac switching characteristics ....................................... 10 switching waveforms .................................................... 11 autostore/power-up recall ....................................... 14 switching waveforms .................................................... 14 software controlled store/recall cycle ................ 15 switching waveforms .................................................... 15 hardware store cycle ................................................. 16 switching waveforms .................................................... 16 truth table for sram operations ................................ 17 ordering information ...................................................... 18 ordering code definitions ..... .................................... 18 package diagrams .......................................................... 19 acronyms ........................................................................ 20 document conventions ................................................. 20 units of measure ....................................................... 20 document history page ................................................. 21 sales, solutions, and legal information ...................... 23 worldwide sales and design s upport ......... .............. 23 products .................................................................... 23 psoc? solutions ...................................................... 23 cypress developer community ................................. 23 technical support ................. .................................... 23 cy14v104la cy14v104na document number: 001-53954 rev. *g page 3 of 23 pinouts figure 1. pin diagram ? 48-ball fbga we v ccq a 11 a 10 v cap a 6 a 0 a 3 ce nc nc dq 0 a 4 a 5 nc dq 2 dq 3 nc v ss a 9 a 8 oe v ss a 7 nc nc v cc a 17 a 2 a 1 nc v ccq dq 4 nc dq 5 dq 6 nc dq 7 nc a 15 a 14 a 13 a 12 hsb 3 2 6 5 4 1 d e b a c f g h a 16 a 18 nc dq 1 top view ( 8) [4] we v ccq a 11 a 10 v cap a 6 a 0 a 3 ce dq 10 dq 8 dq 9 a 4 a 5 dq 13 dq 12 dq 14 dq 15 v ss a 9 a 8 oe v ss a 7 dq 0 bhe v cc a 17 a 2 a 1 ble v ccq dq 2 dq 1 dq 3 dq 4 dq 5 dq 6 dq 7 a 15 a 14 a 13 a 12 hsb 3 2 6 5 4 1 d e b a c f g h a 16 nc nc dq 11 (not to scale) top view ( 16) [4] (not to scale) pin definitions pin name i/o type description a 0 ?a 18 input address inputs used to select one of the 524 ,288 bytes of the nvsram for 8 configuration. a 0 ?a 17 address inputs used to select one of the 262,144 words of the nvsram for 16 configuration. dq 0 ?dq 7 input/output bidirectional data i/o lines for 8 configuration. used as input or output lines depending on operation. dq 0 ?dq 15 bidirectional data i/o lines for 16 configuration. used as input or output lines depending on operation. we input write enable input, ac tive low. when selected low, data on the i/o pins is written to the specific address location. ce input chip enable input, active low. when low, selects the chip. when high, deselects the chip. oe input output enable, active low. the active low oe input enables the data output buffers during read cycles. i/o pins are tri-stated on deasserting oe high. bhe input byte high enable, active low. controls dq 15 ?dq 8 . ble input byte low enable, active low. controls dq 7 ?dq 0 . v ss ground ground for the device. must be co nnected to the ground of the system. v cc power supply power supply inputs to the core of the device. v ccq power supply power supply inputs for the inputs and outputs of the device. hsb input/output hardware store busy (hsb ). output: indicates busy status of nvsram when low. after each hardware and software store operation, hsb is driven high for a short time (t hhhd ) with standard output high current and then a weak internal pull-up resistor keeps this pin high (external pull-up resistor connection optional). input: hardware store implemented by pulling this pin low externally. v cap power supply autostore capacitor. supplies power to the nvsram during power loss to store data from sram to non-volatile elements. nc no connect no connect. this pin is not connected to the die. note 4. address expansion for 8-mbit. nc pin not connected to die. cy14v104la cy14v104na document number: 001-53954 rev. *g page 4 of 23 device operation the cy14v104la/cy14v104na nvsram is made up of two functional components paired in the same physical cell. they are a sram memory cell and a non-volatile quantumtrap cell. the sram memory cell operates as a standard fast static ram. data in the sram is transferred to the non-volatile cell (the store operation), or from the non-vo latile cell to the sram (the recall operation). using this unique architecture, all cells are stored and recalled in parallel. during the store and recall operations, sram read and writ e operations are inhibited. the cy14v104la/cy14v104na supports infinite reads and writes similar to a typical sram. in addition, it provides infinite recall operations from the non-volatile cells and up to 1 million store operations. see truth table for sram operations on page 17 for a complete description of read and write modes. sram read the cy14v104la/cy14v104na performs a read cycle when ce and oe are low and we and hsb are high. the address specified on pins a 0?18 or a 0?17 determines which of the 524,288 data bytes or 262,144 words of 16 bits each are accessed. byte enables (bhe , ble ) determine which bytes are enabled to the output, in the case of 16-bit word s. when the read is initiated by an address transition, the output s are valid after a delay of t aa (read cycle 1). if the r ead is initiated by ce or oe , the outputs are valid at t ace or at t doe , whichever is later (read cycle 2). the data output repeatedly responds to address changes within the t aa access time without the need fo r transitions on any control input pins. this remains valid until another address change or until ce or oe is brought high, or we or hsb is brought low. sram write a write cycle is performed when ce and we are low and hsb is high. the address inputs must be stable before entering the write cycle and must re main stable until ce or we goes high at the end of the cycle. the data on the common i/o pins dq 0?15 are written into the memory if the data is valid t sd before the end of a we controlled write or bef ore the end of an ce controlled write. the byte enable inputs (bhe , ble ) determine which bytes are written, in the case of 16-b it words. it is recommended that oe be kept high duri ng the entire write cycle to avoid data bus contention on common i/o lines. if oe is left low, internal circuitry turns off the output buffers t hzwe after we goes low. autostore operation the cy14v104la/cy14v104na stores data to the nvsram using one of the following three storage operations: hardware store activated by hsb ; software store activated by an address sequence; autostore on device power-down. the autostore operation is a unique feature of quantumtrap technology and is enabled by default on the cy14v104la/cy14v104na. during a normal operation, the device draws current from v cc to charge a capacitor connected to the v cap pin. this stored charge is used by the chip to perform a single store operation. if the voltage on the v cc pin drops below v switch , the part automatically disconnects the v cap pin from v cc . a store operation is initiated with power provided by the v cap capacitor. note if a capacitor is not connected to v cap pin, autostore must be disabled using the soft sequence specified in preventing autostore on page 6 . if autostore is enabled without a capacitor on v cap pin, the device attempts an autostore operation without sufficient charge to complete th e store. this may corrupt the data stored in nvsram. figure 2 shows the proper connection of the storage capacitor (v cap ) for automatic store operation. refer to dc electrical characteristics on page 7 for the size of v cap . the voltage on the v cap pin is driven to v cc by a regulator on the chip. a pull-up should be placed on we to hold it inactive during power-up. this pull-up is effective only if the we signal is tristate during power-up. many mpus tristate their controls on power-up. this should be verified when using the pull-up. when the nvsram comes out of power-on-recall, the mpu must be active or the we held inactive until the mpu comes out of reset. to reduce unnecessary non-volatile stores, autostore and hardware store operations are ignored unless at least one write operation has taken place since the most recent store or recall cycle. software initiat ed store cycles are performed regardless of whether a write operation has taken place. figure 2. autostore mode hardware store operation the cy14v104la/cy14v104na provides the hsb pin to control and acknowledge the store operations. use the hsb pin to request a hardware store cycle. when the hsb pin is driven low, the cy14v104la/cy14v104na conditionally initiates a store operation after t delay . an actual store cycle only begins if a write to the sram has taken place since the last store or recall cycle. the hsb pin also acts as an open drain driver (internal 100 k ? weak pull-up resistor) that is internally driven low to indicate a busy condition when the store (initiated by any means) is in progress. note after each hardware and software store operation hsb is driven high for a short time (t hhhd ) with standard output high current and then remains high by internal 100 k ? pull-up resistor. sram write operations that are in progress when hsb is driven low by any means are given time (t delay ) to complete before the store operation is initiated. however, any sram write cycles requested after hsb goes low are inhibited until hsb returns high. in case the write latch is not set, hsb is not driven low by the cy14v104la/cy14v104na. but any sram read and write cycles are inhibited until hsb is returned high by mpu or other external source. during any store operation, regardless of how it is initiated, the cy14v104la/cy14v104na continues to drive the hsb pin 0.1 uf v cc 10 kohm v cap we v cap v ss v ccq v ccq v cc 0.1 uf cy14v104la cy14v104na document number: 001-53954 rev. *g page 5 of 23 low, releasing it only when the store is complete. upon completion of the store operation, the cy14v104la/cy14v104na remains disabled until the hsb pin returns high. leave the hsb unconnected if it is not used. hardware recall (power-up) during power-up or after any low power condition (v cc cy14v104la cy14v104na document number: 001-53954 rev. *g page 7 of 23 maximum ratings exceeding maximum ratings may impair the useful life of the device. these user guidelines are not tested. storage temperature ..... ............ ............... ?65 ? c to +150 ? c maximum accumulated storage time at 150 ? c ambient temperature ...................... 1000 h at 85 ? c ambient temperature ..................... 20 years maximum junction temperature ................................. 150 ? c supply voltage on v cc relative to v ss ...........?0.5 v to 4.1 v supply voltage on v ccq relative to v ss ......?0.5 v to 2.45 v voltage applied to outputs in high z state ..................................?0.5 v to v ccq + 0.5 v input voltage .....................................?0.5 v to v ccq + 0.5 v transient voltage (< 20 ns) on any pin to ground potential ...............?2.0 v to v ccq + 2.0 v package power dissipation capability (t a = 25 c) ................................................. 1.0 w surface mount pb soldering temperature (3 seconds) ........ .............. .............. ..... +260 ? c dc output current (1 output at a time, 1s duration) .... 15 ma static discharge voltage (per mil-std-883, method 3015) .............. ........... > 2001 v latch up current..................................................... > 140 ma operating range range ambient temperature v cc v ccq industrial ?40 ? c to +85 ? c3.0 v ? 3.6 v 1.65 v ? 1.95 v dc electrical characteristics over the operating range parameter description test conditions min typ [9] max unit v cc power supply voltage ? 3.0 3.3 3.6 v v ccq 1.65 1.8 1.95 v i cc1 average v cc current t rc = 25 ns t rc = 45 ns values obtained without output loads (i out = 0 ma) ??70ma ??52ma i ccq1 average v ccq current ? ? 15 ma ??10ma i cc2 average v cc current during store all inputs don?t care, v cc = max average current for duration t store ??10ma i cc3 average v cc current at t rc = 200 ns, v cc(typ) , 25 c all inputs cycling at cmos levels. values obtained without output loads (i out = 0 ma). ?35?ma i ccq3 average v ccq current at t rc = 200 ns, v ccq(typ) , 25 c ?5?ma i cc4 average v cap current during autostore cycle all inputs don?t care. average current for duration t store ??8ma i sb v cc standby current ce > (v cc ? 0.2 v). v in < 0.2 v or > (v cc ? 0.2 v). standby current level after non-volatile cycle is complete. inputs are static. f = 0 mhz. ??8ma i ix [10] input leakage current (except hsb ) v ccq = max, v ss < v in < v ccq ?1 ? +1 ? a input leakage current (for hsb )v ccq = max, v ss < v in < v ccq ?100 ? +1 ? a i oz off-state output leakage current v ccq = max, v ss < v out < v ccq , ce or oe > v ih or bhe /ble > v ih or we < v il ?1 ? +1 ? a v cap [11] storage capacitor between v cap pin and v ss 61 68 180 ? f v vcap [9, 12] maximum voltage driven on v cap pin by the device v cc = max ? ? v cc v notes 9. typical values are at 25 c, v cc = v cc(typ) and v ccq = v ccq(typ) . not 100% tested. 10. the hsb pin has i out = -4 a for v oh of 1.07 v when both active high and low driver s are disabled. when they are enabled standard v oh and v ol are valid. this parameter is characterized but not tested. 11. min v cap value guarantees that there is a sufficient charge available to complete a successful autostore operation. max v cap value guarantees that the capacitor on v cap is charged to a minimum voltage during a power-up recall cycle so that an immediate power-down cycle can complete a successful autostore. therefore it is always recommended to use a capacitor within the specified min and max limits. refer application note an43593 for more details on v cap options. 12. maximum voltage on v cap pin (v vcap ) is provided for guidance when choosing the v cap capacitor. the voltage rating of the v cap capacitor across the operating temperature range should be higher than the v vcap voltage. cy14v104la cy14v104na document number: 001-53954 rev. *g page 8 of 23 v ih input high voltage ? 0.7 v ccq ?v ccq + 0.3 v v il input low voltage ? ? 0.3 ? 0.3 v ccq v v oh output high voltage i out = ?1 ma v ccq ? 0.45 ??v v ol output low voltage i out = 2 ma ? 0.45 v dc electrical characteristics (continued) over the operating range parameter description test conditions min typ [9] max unit data retention and endurance over the operating range parameter description min unit data r data retention 20 years nv c non-volatile store operation 1,000 k capacitance parameter [13] description test conditions max unit c in input capacitance (except ble , bhe and hsb ) t a = 25 ? c, f = 1 mhz, v cc = v cc (typ), v ccq = v ccq (typ) 7 pf input capacitance (for ble , bhe and hsb ) 8pf c out output capacitance (except hsb )7pf output capacitance (for hsb )8pf thermal resistance in the following table, the thermal resistance parameters are listed. parameter [13] description test conditions 48-ball fbga unit ? ja thermal resistance (junction to ambient) test conditions follow standard test methods and proce- dures for measuring thermal impedance, in accordance with eia/jesd51. 46.09 ? c/w ? jc thermal resistance (junction to case) 7.84 ? c/w note 13. these parameters are guaranteed by design but not tested. cy14v104la cy14v104na document number: 001-53954 rev. *g page 9 of 23 ac test conditions input pulse levels ................................................0 v to 1.8 v input rise and fall times (10%?90%) ......................... < 1.8 ns input and output timing reference levels ....................... 0.9 v ac test loads figure 3. ac test loads 1.8 v output 5 pf r1 r2 450 ? 1.8 v output 30 pf r1 r2 450 ? for tri-state specs 450 ? 450 ? cy14v104la cy14v104na document number: 001-53954 rev. *g page 10 of 23 ac switching characteristics over the operating range parameters [14] description 25 ns 45 ns unit cypress parameter alt parameter min max min max sram read cycle t ace t acs chip enable access time ? 25 ? 45 ns t rc [15] t rc read cycle time 25 ? 45 ? ns t aa [16] t aa address access time ? 25 ? 45 ns t doe t oe output enable to data valid ? 12 ? 20 ns t oha [16] t oh output hold after address change 3 ? 3? ns t lzce [17, 18] t lz chip enable to output active 3 ? 3? ns t hzce [17, 18] t hz chip disable to output inactive ? 10 ? 15 ns t lzoe [17, 18] t olz output enable to output active 0 ? 0? ns t hzoe [17, 18] t ohz output disable to output inactive ? 10 ? 15 ns t pu [17] t pa chip enable to power active 0 ? 0? ns t pd [17] t ps chip disable to power standby ? 25 ? 45 ns t dbe ? byte enable to data valid ? 12 ? 20 ns t lzbe [17] ? byte enable to output active 0 ? 0 ? ns t hzbe [17] ? byte disable to output inactive ? 10 ? 15 ns sram write cycle t wc t wc write cycle time 25 ? 45 ? ns t pwe t wp write pulse width 20 ? 30 ? ns t sce t cw chip enable to end of write 20 ? 30 ? ns t sd t dw data setup to end of write 10 ? 15 ? ns t hd t dh data hold after end of write 0 ? 0? ns t aw t aw address setup to end of write 20 ? 30 ? ns t sa t as address setup to start of write 0 ? 0? ns t ha t wr address hold after end of write 0 ? 0? ns t hzwe [17, 18, 19] t wz write enable to output disable ? 10 ? 15 ns t lzwe [17, 18] t ow output active after end of write 3? 3? ns t bw ? byte enable to end of write 20 ? 30 ? ns notes 14. test conditions assume signal transition time of 1.8 ns or less, timing reference levels of v ccq /2, input pulse levels of 0 to v cc q(typ) , and output loading of the specified i ol /i oh and load capacitance shown in figure 3 on page 9 . 15. we must be high during sram read cycles. 16. device is continuously selected with ce , oe and bhe / ble low. 17. these parameters are guaranteed by design but not tested. 18. measured 200 mv from steady state output voltage. 19. if we is low when ce goes low, the outputs remain in the high impedance state. 20. hsb must remain high during read and write cycles. cy14v104la cy14v104na document number: 001-53954 rev. *g page 11 of 23 switching waveforms figure 4. sram read cycle #1 (address controlled) [21, 22, 23] figure 5. sram read cycle #2 (ce and oe controlled) [21, 23, 24] ? address data output address valid previous data valid output data valid t rc t aa t oha address valid address data output output data valid standby active high impedance ce oe bhe, ble i cc t hzce t rc t ace t aa t lzce t doe t lzoe t dbe t lzbe t pu t pd t hzbe t hzoe notes 21. we must be high during sram read cycles. 22. device is continuously selected with ce , oe and bhe / ble low. 23. hsb must remain high during read and write cycles. 24. typical values are at 25 c, v cc = v cc(typ) and v ccq = v ccq(typ) . not 100% tested. cy14v104la cy14v104na document number: 001-53954 rev. *g page 12 of 23 figure 6. sram write cycle #1 (we controlled) [25, 26, 27, 28] figure 7. sram write cycle #2 (ce controlled) [25, 26, 27, 28] switching waveforms (continued) data output data input input data valid high impedance address valid address previous data t wc t sce t ha t bw t aw t pwe t sa t sd t hd t hzwe t lzwe we bhe, ble ce data output data input input data valid high impedance address valid address t wc t sd t hd bhe, ble we ce t sa t sce t ha t bw t pwe notes 25. hsb must remain high during read and write cycles. 26. bhe and ble are applicable for x16 configuration only. 27. if we is low when ce goes low, the outputs remain in the high impedance state. 28. ce or we must be > v ih during address transitions. cy14v104la cy14v104na document number: 001-53954 rev. *g page 13 of 23 figure 8. sram write cycle #3 (bhe and ble controlled) [29, 30, 31, 32] switching waveforms (continued) data output data input input data valid high impedance address valid address t wc t sd t hd bhe, ble we ce t sce t sa t bw t ha t aw t pwe notes 29. hsb must remain high during read and write cycles. 30. bhe and ble are applicable for 16 configuration only. 31. if we is low when ce goes low, the outputs remain in the high impedance state. 32. ce or we must be > v ih during address transitions. cy14v104la cy14v104na document number: 001-53954 rev. *g page 14 of 23 autostore/power-up recall over the operating range parameter description cy14v104la/cy14v104na unit min max t hrecall [33] power-up recall duration ? 20 ms t store [34] store cycle duration ? 8 ms t delay [35] time allowed to comp lete sram write cycle ? 25 ns v switch low voltage trigger level for v cc ? 2.90 v v iodis [36] i/o disable voltage on v ccq ? 1.50 v t vccrise [39] v cc rise time 150 ? ? s v hdis [39] hsb output disable voltage on v cc ? 1.9 v t lzhsb [39] hsb to output active time ? 5 ? s t hhhd [39] hsb high active time ? 500 ns switching waveforms figure 9. autostore or power-up recall [37] v iodis t vccrise t store t store t hhhd t hhhd t delay t delay t lzhsb t lzhsb t hrecall t hrecall hsb out autostore power- up recall read & write inhibited ( rwi ) power-up recall read & write brown out autostore power-up recall read & write power down autostore note note note v switch v hdis read & write brown out i/o disable v cc v cc v ccq v ccq v ccq note 35 38 35 38 notes 33. t hrecall starts from the time v cc rises above v switch . 34. if an sram write has not taken place since the last non-volatile cycle, no autostore or hardware store takes place. 35. on a hardware store and autostore initiation, sram write operation continues to be enabled for time t delay . 36. hsb will not be defined below v iodis voltage. 37. read and write cycles are ignored during store, recall, and while v cc is below v switch . 38. during power-up and power-down, hsb glitches when hsb pin is pulled up through an external resistor. 39. these parameters are guaranteed by design but not tested. cy14v104la cy14v104na document number: 001-53954 rev. *g page 15 of 23 software controlled store/recall cycle over the operating range parameters [40, 41] description 25 ns 45 ns unit min max min max t rc store/recall initiation cycle time 25 ? 45 ? ns t sa address setup time 0? 0? ns t cw clock pulse width 20 ? 30 ? ns t ha address hold time 0? 0? ns t recall recall duration ? 200 ? 200 ? s switching waveforms figure 10. ce and oe controlled software store/recall cycle [41] figure 11. autostore enable/disable cycle t rc t rc t sa t cw t cw t sa t ha t lzce t hzce t ha t ha t ha t store /t recall t hhhd t lzhsb high impedance address #1 address #6 address ce oe hsb (store only) dq (data) rwi t delay note 42 t rc t rc t sa t cw t cw t sa t ha t lzce t hzce t ha t ha t ha t delay address #1 address #6 address ce oe dq (data) t ss note 42 notes 40. the software sequence is clocked with ce controlled or oe controlled reads. 41. the six consecutive addr esses must be read in the order listed in table 1 on page 5 . we must be high during a ll six consecutive cycles. 42. dq output data at the sixth read may be invalid since the output is disabled at t delay time. cy14v104la cy14v104na document number: 001-53954 rev. *g page 16 of 23 hardware store cycle over the operating range parameters description cy14v104la/cy14v104na unit min max t dhsb hsb to output active time when write latch not set ? 25 ns t phsb hardware store pulse width 15 ? ns t ss [43, 44] soft sequence processing time ? 100 ? s switching waveforms figure 12. hardware store cycle [45] figure 13. soft sequence processing [43, 44] t phsb t phsb t delay t dhsb t delay t store t hhhd t lzhsb write latch set write latch not set hsb (in) hsb (out) dq (data out) rwi hsb (in) hsb (out) rwi hsb pin is driven high to v cc only by internal sram is disabled as long as hsb (in) is driven low . hsb driver is disabled t dhsb 100 kohm resistor, address #1 address #6 address #1 address #6 soft sequence command t ss t ss ce address v cc t sa t cw soft sequence command t cw notes 43. this is the amount of time it takes to take action on a soft sequence command. vcc power must remain high to effectively reg ister command. 44. commands such as store and recall lock out i/o until operation is complete which further increases this time. see the specif ic command. 45. if an sram write has not taken place since the last non -volatile cycle, no autostore or hardware store takes place. cy14v104la cy14v104na document number: 001-53954 rev. *g page 17 of 23 truth table for sram operations hsb should remain high for sram operations. table 2. truth table for 8 configuration ce we oe inputs/outputs [46] mode power h x x high z deselect/power-down standby l h l data out (dq 0 ?dq 7 ) read active l h h high z output disabled active l l x data in (dq 0 ?dq 7 ) write active table 3. truth table for 16 configuration ce we oe bhe [47] ble [47] inputs/outputs [46] mode power h x x x x high z deselect/power-down standby l x x h h high z output disabled active lhllldata out (dq 0 ?dq 15 ) read active l h l h l data out (dq 0 ?dq 7 ); dq 8 ?dq 15 in high z read active l h l l h data out (dq 8 ?dq 15 ); dq 0 ?dq 7 in high z read active l h h l l high z output disabled active l h h h l high z output disabled active l h h l h high z output disabled active llxlldata in (dq 0 ?dq 15 ) write active llxhldata in (dq 0 ?dq 7 ); dq 8 ?dq 15 in high z write active llxlhdata in (dq 8 ?dq 15 ); dq 0 ?dq 7 in high z write active notes 46. data dq 0 ?dq 7 for 8 configuration and data dq 0 ?dq 15 for 16 configuration. 47. bhe and ble are applicable for 16 configuration only. cy14v104la cy14v104na document number: 001-53954 rev. *g page 18 of 23 ordering code definitions ordering information speed (ns) ordering code package diagram package type operating range 25 cy14v104la-ba25xit 51-85128 48-ball fbga industrial cy14v104la-ba25xi cy14v104na-ba25xit cy14v104na-ba25xi 45 cy14v104la-ba45xit cy14v104la-ba45xi CY14V104NA-BA45XIt CY14V104NA-BA45XI contact your local cypress sales repres entative for availability of these parts. option: t - tape and reel blank - std. speed: 25 - 25 ns 45 - 45 ns data bus: l - 8 n - 16 density: 104 - 4 mb voltage: v - 3.3 v v cc , 1.8 v v ccq cypress cy 14 v 104 l a - ba 25 x i t 14 - nvsram x - pb-free temperature: i - industrial (?40 to 85 c) die revision: blank - no rev a - 1 st rev package: ba - 48-ball fbga cy14v104la cy14v104na document number: 001-53954 rev. *g page 19 of 23 package diagrams figure 14. 48-ball fbga (6 10 1.2 mm) ba48b, 51-85128 51-85128 *f cy14v104la cy14v104na document number: 001-53954 rev. *g page 20 of 23 acronyms document conventions units of measure acronym description bhe byte high enable ble byte low enable ce chip enable cmos complementary metal oxide semiconductor eia electronic industries alliance fbga fine-pitch ball grid array hsb hardware store busy i/o input/output nvsram non-volatile static random access memory oe output enable rohs restriction of hazardous substances sram static random access memory we write enable symbol unit of measure c degree celsius k ? kilo ohms mhz mega hertz ? a micro amperes ma milli amperes ? f micro farads ? s micro seconds ms milli seconds ns nano seconds ? ohms % percent pf pico farads v volts w watts cy14v104la cy14v104na document number: 001-53954 rev. *g page 21 of 23 document history page document title: cy14v104la/cy14v104na, 4-mbit (512 k 8 / 256 k 16) nvsram document number: 001-53954 rev. ecn no. orig. of change submission date description of change ** 2729117 gvch / aesa 07/02/2009 new data sheet. *a 2826127 gvch / aesa 12/11/2009 removed commercial temperature related specs changed part number from cy14a104l/cy14a104n to cy14v104la/cy14v104na removed 20 ns access speed specs removed 44/54 tsop ii package related information updated store cycles to quantumtrap from 200k to 1 million figure 3: updated autostore mode page 4: updated hardware store (hsb ) operation description page 5: updated software store operation description maximum ratings: supply voltage on v ccq relative to gnd from ?0.5v to 2.5v to ?0.5v to 2.45v added i ccq1 and i ccq3 for v ccq operation updated i cc4 test condition updated footnote 8 updated v ih /v il as 70%/30% of v ccq updated v oh test condition. updated input rise and fall times (10% - 90%) from 3ns to 1.8 ns updated footnote 19, 22 and added footnote 20, 25 updated v iodis parameter value from 1.6v to 1.5v updated figure 10, 11 and 12 *b 2858300 gvch 01/19/2010 changed latch up current from 200 ma to 140 ma. changed status from advance to preliminary. added contents. *c 2951754 gvch / aesa 06/14/2010 pin definitions : added more clarity on hsb pin operation hardware store operation : added more clarity on hsb pin operation ta b l e 1 : added more clarity on status of bhe /ble pin operation updated hsb pin operation in figure 9 updated footnote 22 *d 3115647 gvch 12/20/2010 change datasheet status from ?preliminary? to ?final? 48 fbga package: 16 mb address expansion is not supported changed i sb and i cc4 value from 5 ma to 8 ma changed i ccq1 value from 25 ma to 15 ma for 25 ns access speed and 15 ma to 10 ma for 45 ns access speed. added acronyms and units of measure table *e 3150253 gvch 01/21/11 updated input capacitance for bhe and ble pin *f 3303659 gvch 07/06/2011 updated dc electrical characteristics (added note 11 and referred the same note in v cap parameter). updated ac switching characteristics (added note 14 and referred the same note in parameters). updated thermal resistance (values of ? ja for 48-ball fbga package). updated package diagrams . cy14v104la cy14v104na document number: 001-53954 rev. *g page 22 of 23 *g 4075544 gvch 07/24/2013 updated pin definitions : updated description of hsb pin (added more clarity). updated device operation : updated autostore operation (removed sentence ?the hsb signal is monitored by the system to detect if an autostore cycle is in progress.?). removed best practices. updated maximum ratings : removed ?ambient temperature with power applied? and included ?maximum junction temperature?. updated dc electrical characteristics : added v vcap parameter and its details. referred note 9 in v vcap parameter, added note 12 and referred the same note in v vcap parameter. updated in new template. completing sunset review. document history page (continued) document title: cy14v104la/cy14v104na, 4-mbit (512 k 8 / 256 k 16) nvsram document number: 001-53954 rev. ecn no. orig. of change submission date description of change document number: 001-53954 rev. *g revised july 24, 2013 page 23 of 23 all products and company names mentioned in this document may be the trademarks of their respective holders. cy14v104la cy14v104na ? cypress semiconductor corporation, 2009-2013. the information contained herein is subject to change without notice. cypress s emiconductor corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a cypress product. nor does it convey or imply any license under patent or other rights. cypress products are not warranted nor intended to be used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement wi th cypress. furthermore, cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. the inclusion of cypress products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies cypress against all charges. any source code (software and/or firmware) is owned by cypress semiconductor corporation (cypress) and is protected by and subj ect to worldwide patent protection (united states and foreign), united states copyright laws and internatio nal treaty provisions. cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of, and compile the cypress source code and derivative works for the sole purpose of creating custom software and or firmware in su pport of licensee product to be used only in conjunction with a cypress integrated circuit as specified in the applicable agreement. any reproduction, modification, translation, compilation, or repre sentation of this source code except as specified above is prohibited without the express written permission of cypress. disclaimer: cypress makes no warranty of any kind, express or implied, with regard to this material, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. cypress reserves the right to make changes without further notice to t he materials described herein. cypress does not assume any liability arising out of the application or use of any product or circuit described herein. cypress does not authori ze its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. the inclusion of cypress? prod uct in a life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies cypress against all charges. use may be limited by and subject to the applicable cypress software license agreement. sales, solutions, and legal information worldwide sales and design support cypress maintains a worldwide network of offices, solution center s, manufacturer?s representatives, and distributors. to find t he office closest to you, visit us at cypress locations . products automotive cypress.co m/go/automotive clocks & buffers cypress.com/go/clocks interface cypress. com/go/interface lighting & power control cypress.com/go/powerpsoc cypress.com/go/plc memory cypress.com/go/memory psoc cypress.com/go/psoc touch sensing cyp ress.com/go/touch usb controllers cypress.com/go/usb wireless/rf cypress.com/go/wireless psoc ? solutions 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