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| to our customers, old company name in catalogs and other documents on april 1 st , 2010, nec electronics corporation merged with renesas technology corporation, and renesas electronics corporation took over all the business of both companies. therefore, although the old company name remains in this document, it is a valid renesas electronics document. we appreciate your understanding. renesas electronics website: http://www.renesas.com april 1 st , 2010 renesas electronics corporation issued by: renesas electronics corporation ( http://www.renesas.com ) send any inquiries to http://www.renesas.com/inquiry .
notice 1. all information included in this document is current as of th e date this document is issued. such information, however, is subject to change without any prior notice. before purchasing or using any renesas electronics products listed herein, please confirm the latest product information with a renesas electronics sales office. also, please pay regular and careful attention to additional and different information to be disclosed by renesas electronics such as that disclosed through our website. 2. renesas electronics does not assume any liability for infringement of patents, copyrights, or other intellectual property ri ghts of third parties by or arising from the use of renesas electronics products or technical information described in this document . no license, express, implied or otherwise, is granted hereby under any patents, copyrights or other intellectual property right s of renesas electronics or others. 3. you should not alter, modify, copy, or otherwise misappropriate any renesas electronics product, whether in whole or in part . 4. descriptions of circuits, software and other related information in this document are provided only to illustrate the operat ion of semiconductor products and application examples. you are fully responsible for the incorporation of these circuits, software, and information in the design of your equipment. renesas electronics assumes no responsibility for any losses incurred by you or third parties arising from the use of these circuits, software, or information. 5. when exporting the products or technology described in this document, you should comply with the applicable export control laws and regulations and follow the procedures required by such laws and regulations. you should not use renesas electronics products or the technology de scribed in this document for any purpose relating to military applications or use by the military, including but not limited to the development of weapons of mass destruction. renesas electronics products and technology may not be used for or incorporated into any products or systems whose manufacture, use, or sale is prohibited under any applicable domestic or foreign laws or regulations. 6. renesas electronics has used reasonable care in preparing the information included in this document, but renesas electronics does not warrant that such information is error free. renesas electronics assumes no liability whatsoever for any damages incurred by you resulting from errors in or om issions from the information included herein. 7. renesas electronics products are classified according to the following three quality grades: ?standard?, ?high quality?, an d ?specific?. the recommended applications for each renesas electronics product depends on the product?s quality grade, as indicated below. you must check the quality grade of each renesas electronics product before using it in a particular application. you may not use any renesas electronics product for any application categorized as ?specific? without the prior written consent of renesas electronics. further, you may not use any renesas electronics product for any application for which it is not intended without the prior written consent of renesas electronics. renesas electronics shall not be in any way liable for any damages or losses incurred by you or third parties arising from the use of any renesas electronics product for a n application categorized as ?specific? or for which the product is not intended where you have failed to obtain the prior writte n consent of renesas electronics. the quality grade of each renesas electronics product is ?standard? unless otherwise expressly specified in a renesas electronics data sheets or data books, etc. ?standard?: computers; office equipment; communications equipment; test and measurement equipment; audio and visual equipment; home electronic appliances; machine tools; personal electronic equipment; and industrial robots. ?high quality?: transportation equipment (automobiles, trains, ship s, etc.); traffic control systems; anti-disaster systems; an ti- crime systems; safety equipment; and medical equipment not specifically designed for life support. ?specific?: aircraft; aerospace equipment; submersible repeaters; nuclear reactor control systems; medical equipment or systems for life support (e.g. artificial life support devices or systems), surgical implantations, or healthcare intervention (e.g. excision, etc.), and any other applications or purposes that pose a direct threat to human life. 8. you should use the renesas electronics products described in this document within the range specified by renesas electronics , especially with respect to the maximum rating, operating supply voltage range, movement power voltage range, heat radiation characteristics, installation and other product characteristics. renesas electronics shall have no liability for malfunctions o r damages arising out of the use of renesas electronics products beyond such specified ranges. 9. although renesas electronics endeavors to improve the quality and reliability of its products, semiconductor products have specific characteristics such as the occurrence of failure at a certain rate and malfunctions under certain use conditions. fur ther, renesas electronics products are not subject to radiation resistance design. please be sure to implement safety measures to guard them against the possibility of physical injury, and injury or damage caused by fire in the event of the failure of a renesas electronics product, such as safety design for hardware and software including but not limited to redundancy, fire control and malfunction prevention, appropriate treatment for aging degradation or any other appropriate measures. because the evaluation of microcomputer software alone is very difficult, please evaluate the safety of the final products or system manufactured by you. 10. please contact a renesas electronics sales office for details as to environmental matters such as the environmental compatibility of each renesas electronics product. please use re nesas electronics products in compliance with all applicable laws and regulations that regulate the inclusion or use of c ontrolled substances, including without limitation, the eu rohs directive. renesas electronics assumes no liability for damages or losses occurring as a result of your noncompliance with applicable laws and regulations. 11. this document may not be reproduced or duplicated, in any fo rm, in whole or in part, without prior written consent of renes as electronics. 12. please contact a renesas electronics sales office if you have any questions regarding the information contained in this document or renesas electronics products, or if you have any other inquiries. (note 1) ?renesas electronics? as used in this document means renesas electronics corporation and also includes its majority- owned subsidiaries. (note 2) ?renesas electronics product(s)? means any product developed or manufactured by or for renesas electronics. preliminary: the specifications of this device are subject to change without notice. please contact your nearest renesas technology's sales dept. regarding specifications. rev.0.10, may.15.2003, page 1 of 22 hm64ylb36514 series 16m synchronous late write fast static ram (512-kword 36-bit, register-latch mode) rej03c0039-0001z preliminary rev.0.10 may.15.2003 description the hm64ylb36514 is a synchronous fast static ram organized as 512-kword 36-bit. it has realized high speed access time by employing the most advanced cmos process and high speed circuit designing technology. it is most appropriate for the application which requires high speed, high density memory and wide bit width configuration, such as cache and buffer memory in system. it is packaged in standard 119- bump bga. note: all power supply and ground pins must be connected for proper operation of the device. features ? 2.5 v 5% operation and 1.5 v (v ddq ) ? 16m bit density ? internal self-timed late write ? byte write control (4 byte write selects, one for each 9-bit) ? optional 18 configuration ? hstl compatible i/o ? programmable impedance output drivers ? differential pseudo-hstl clock inputs ? asynchronous g output control ? asynchronous sleep mode ? fc-bga 119pin package with sram jedec standard pinout ? limited set of boundary scan jtag ieee 1149.1 compatible ? protocol: single differential clock register-latch mode hm64ylb36514 series rev.0.10, may.15.2003, page 2 of 22 ordering information type no. organization access time cycle time package hm64ylb36514bp-6h 512k 36 5.5 ns 6.5 ns 119-bump 1.27 mm 14 mm 22 mm bga (bp-119e) pin arrangement 1 2 3 4 5 6 7 a v dd q sa14 sa13 nc sa6 sa7 v dd q b nc sa15 sa12 nc sa5 sa9 nc c nc sa16 sa11 v dd sa4 sa8 nc d dqc7 dqc8 v ss zq v ss dqb8 dqb7 e dqc5 dqc6 v ss ss v ss dqb6 dqb5 f v dd q dqc4 v ss g v ss dqb4 v dd q g dqc3 dqc2 swec nc sweb dqb2 dqb3 h dqc1 dqc0 v ss nc v ss dqb0 dqb1 j v dd q v dd v ref v dd v ref v dd v dd q k dqd1 dqd0 v ss k v ss dqa0 dqa1 l dqd3 dqd2 swed k swea dqa2 dqa3 m v dd q dqd4 v ss swe v ss dqa4 v dd q n dqd5 dqd6 v ss sa17 v ss dqa6 dqa5 p dqd7 dqd8 v ss sa0 v ss dqa8 dqa7 r nc sa10 m1 v dd m2 sa1 nc t nc nc sa18 sa3 sa2 nc zz u v dd q tms tdi tck tdo nc v dd q (top view) hm64ylb36514 series rev.0.10, may.15.2003, page 3 of 22 block diagram read add. reg. write add. reg. (way0) 512k 36 memory array ss reg. swe reg. output latch din reg. sa0 to sa18 swe ss 1 0 k 1 0 sa0 to sa18 compare swex 1st reg. swex (x: a to d) swex 2nd reg. byte write control output enable dqxn (x: a to d, n: 0 to 8) match0 impedance control zq g hm64ylb36514 series rev.0.10, may.15.2003, page 4 of 22 pin descriptions name i/o type descriptions notes v dd supply core power supply v ss supply ground v ddq supply output power supply v ref supply input reference, provides input reference voltage k input clock input, active high k input clock input, active low ss input synchronous chip select swe input synchronous write enable san input synchronous address input n: 0 to 18 swex input synchronous byte write enables x: a to d g input asynchronous output enable zz input power down mode select zq input output impedance control 1 dqxn i/o synchronous data input/output x: a to d n: 0 to 8 m1, m2 input output protocol mode select tms input boundary scan test mode select tck input boundary scan test clock tdi input boundary scan test data input tdo output boundary scan test data output nc ? no connection m1 m2 protocol notes v dd v ss synchronous register to latch operation 2 notes: 1. zq is to be connected to v ss via a resistance rq where 175 ? rq 300 ? . if zq = v ddq or open, output buffer impedance will be maximum. 2. there is 1 protocol with mode control input pins (m1, m2). these mode pins are to be tied either v dd or v ss respectively. these mode pins are set at power-up and will not change the states during the sram operates. this sram is tested only in the synchronous register to latch operation. hm64ylb36514 series rev.0.10, may.15.2003, page 5 of 22 truth table zz ss ss ss ss g g g g swe swe swe swe swea swea swea swea sweb sweb sweb sweb swec swec swec swec swed swed swed swed k k k k k operation dq (n) dq (n+1) h sleep mode high-z high-z l h l-h h-l dead (not selected) high-z l h h dead (dummy read) high-z high-z l l l h l-h h-l read d out (a, b, c, d) 0 to 8 l l l l l l l l-h h-l write a, b, c, d byte high-z d in (a, b, c, d) 0 to 8 l l l h l l l l-h h-l write b, c, d byte high-z d in (b, c, d) 0 to 8 l l l l h l l l-h h-l write a, c, d byte high-z d in (a, c, d) 0 to 8 l l l l l h l l-h h-l write a, b, d byte high-z d in (a, b, d) 0 to 8 l l l l l l h l-h h-l write a, b, c byte high-z d in (a, b, c) 0 to 8 l l l h h l l l-h h-l write c, d byte high-z d in (c, d) 0 to 8 l l l l h h l l-h h-l write a, d byte high-z d in (a, d) 0 to 8 l l l l l h h l-h h-l write a, b byte high-z d in (a, b) 0 to 8 l l l h l l h l-h h-l write b, c byte high-z d in (b, c) 0 to 8 l l l h h h l l-h h-l write d byte high-z d in (d) 0 to 8 l l l h h l h l-h h-l write c byte high-z d in (c) 0 to 8 l l l h l h h l-h h-l write b byte high-z d in (b) 0 to 8 l l l l h h h l-h h-l write a byte high-z d in (a) 0 to 8 notes: 1. h: v ih , l: v il , : v ih or v il 2. swe , ss , swea to swed , and sa are sampled at the rising edge of k clock. hm64ylb36514 series rev.0.10, may.15.2003, page 6 of 22 programmable impedance output drivers output buffer impedance can be programmed by terminating the zq pin to v ss through a precision resistor (rq). the value of rq is five times the output impedance desired. the allowable value of rq to guarantee impedance matching with a tolerance of 15% is 250 ? . if the status of zq pin is open, output impedance is maximum value. maximum impedance also occurs with zq connected to v ddq . the impedance update of the output driver occurs when the sram is in high-z. write and deselect operations will synchronously switch the sram into and out of high-z, therefore will trigger an update. the user may choose to invoke asynchronous g updates by providing a g setup and hold about the k clock, to guarantee the proper update. at power up, the output buffer is in high-z. it will take 4,096 cycles for the impedance to be completely updated. hm64ylb36514 series rev.0.10, may.15.2003, page 7 of 22 absolute maximum ratings parameter symbol rating unit notes input voltage on any pin v in ? 0.5 to v ddq + 0.5 v 1, 4 core supply voltage v dd ? 0.5 to +3.13 v 1 output supply voltage v ddq ? 0.5 to +2.1 v 1, 4 operating temperature t opr 0 to +85 c storage temperature t stg ? 55 to +125 c output short-circuit current i out 25 ma latch up current i li 200 ma package junction to top thermal resistance j-top 6.5 c/w 5 package junction to board thermal resistance j-board 12 c/w 5 notes: 1. all voltage is referenced to v ss . 2. permanent device damage may occur if absolute maximum ratings are exceeded. functional operation should be restricted the operation conditions. exposure to higher voltages than recommended voltages for extended periods of time could affect device reliability. 3. these cmos memory circuits have been designed to meet the dc and ac specifications shown in the tables after thermal equilibrium has been established. 4. the following supply voltage application sequence is recommended: v ss , v dd , v ddq , v ref then v in . remember, according to the absolute maximum ratings table, v ddq is not to exceed 2.1 v, whatever the instantaneous value of v ddq . 5. see figure below. j-top thermocouple thermo grease water cold plate sram teflon block jedec/2s2p bga thermal board thermocouple thermo grease water cold plate sram teflon block jedec/2s2p bga thermal board j-board water water hm64ylb36514 series rev.0.10, may.15.2003, page 8 of 22 note: the following dc and ac specifications shown in the tables, this device is tested under the minimum transverse air flow exceeding 500 linear feet per minute. recommended dc operating conditions (ta = 0 to +85 c) parameter symbol min typ max unit notes power supply voltage: core v dd 2.38 2.50 2.63 v power supply voltage: i/o v ddq 1.40 1.50 1.60 v input reference voltage: i/o v ref 0.70 0.75 0.80 v 1 input high voltage v ih v ref + 0.15 ? v ddq + 0.50 v 4 input low voltage v il ? 0.50 ? v ref ? 0.15 v 4 clock differential voltage v dif 0.10 ? v ddq + 0.30 v 2, 3 clock common mode voltage v cm 0.90 ? 1.30 v 3 notes: 1. peak to peak ac component superimposed on v ref may not exceed 5% of v ref . 2. minimum differential input voltage required for differential input clock operation. 3. see figure below. 4. v ref = 0.75 v (typ). differential voltage / common mode voltage v dif v cm v ddq v ss hm64ylb36514 series rev.0.10, may.15.2003, page 9 of 22 dc characteristics (ta = 0 to +85 c, v dd = 2.5 v 5%) parameter symbol min max unit notes input leakage current i li ? 2 a 1 output leakage current i lo ? 5 a 2 standby current i sbzz ? 150 ma 3 v dd operating current, excluding output drivers i dd ? 350 ma 4 quiescent active power supply current i dd2 ? 200 ma 5 maximum power dissipation, including output drivers p ? 2.3 w 6 parameter symbol min typ max unit notes output low voltage v ol v ss ? v ss + 0.4 v 7 output high voltage v oh v ddq ? 0.4 ? v ddq v 8 zq pin connect resistance rq ? 250 ? ? output ?low? current i ol (v ddq /2)/{(rq/5) ? 15%} (v ddq /2)/{(rq/5) + 15%} ma 9, 11 output ?high? current i oh (v ddq /2)/{(rq/5) + 15%} (v ddq /2)/{(rq/5) ? 15%} ma 10, 11 notes: 1. 0 v in v ddq for all input pins (except v ref , zq, m1, m2 pin) 2. 0 v out v ddq , dq in high-z 3. all inputs (except clock) are held at either v ih or v il , zz is held at v ih , i out = 0 ma. specification is guaranteed at +75 c junction temperature. 4. i out = 0 ma, read 50% / write 50%, v dd = v dd max, frequency = min. cycle 5. i out = 0 ma, read 50% / write 50%, v dd = v dd max, frequency = 3 mhz 6. output drives a 12 pf load and switches every cycle. this parameter should be used by the sram designer to determine electrical and package requirements for the sram device. 7. rq = 250 ? , i ol = 6.8 ma 8. rq = 250 ? , i oh = ? 6.8 ma 9. measured at v ol = 1/2 v ddq 10. measured at v oh = 1/2 v ddq 11. the total external capacitance of zq pin must be less than 7.5 pf. hm64ylb36514 series rev.0.10, may.15.2003, page 10 of 22 ac characteristics (ta = 0 to +85 c, v dd = 2.5 v 5%) single differential clock register-latch mode hm64ylb36514bp -6h parameter symbol min max unit notes ck clock cycle time t khkh 6.5 ? ns ck clock high width t khkl 1.2 ? ns ck clock low width t klkh 1.2 ? ns address setup time t avkh 0.4 ? ns 2 data setup time t dvkh 0.4 ? ns 2 address hold time t khax 1.0 ? ns data hold time t khdx 1.0 ? ns clock high to output valid t khqv 1.7 5.5 ns 1 clock low to output valid t klqv 0.5 2.3 ns clock low to output hold t klqx 0.5 ? ns clock low to output low-z ( ss control) t klqx2 0.5 ? ns 1, 4, 6 clock high to output high-z t khqz 0.5 2.3 ns 1, 3, 6 output enable low to output low-z t glqx 0.1 ? ns 1, 4, 6 output enable low to output valid t glqv ? 2.3 ns 1, 4 output enable high to output high-z t ghqz ? 2.3 ns 1, 3 sleep mode recovery time t zzr 20.0 ? ns 5 sleep mode enable time t zze ? 15.0 ns 1, 3, 5 notes: 1. see figure in ?ac test conditions?. 2. parameters may be guaranteed by design, i.e., without tester guardband. 3. transitions are measured 50 mv of output high impedance from output low impedance. 4. transitions are measured 50 mv from steady state voltage. 5. when zz is switching, clock input k must be at the same logic level for the reliable operation. 6. minimum value is verified by design and tested without guardband. hm64ylb36514 series rev.0.10, may.15.2003, page 11 of 22 timing waveforms read cycle-1 k, k q0 q2 q3 ss swe swex dq a2 a3 a4 a1 sa t avkh t avkh t avkh t klqv t klqx t khkh t khkl t klkh q1 t khqv t khax t khax khax t note: zz = v il read cycle-2 ( ss controlled) t khkh t khkl t klkh a3 a4 a1 sa t khax t avkh t avkh t khax swex ss swe t avkh t khax dq q0 q1 q3 t khqz t khqv t klqx2 k, k note: zz = v il hm64ylb36514 series rev.0.10, may.15.2003, page 12 of 22 read cycle-3 ( g controlled) q0 q1 q2 q3 a2 a3 a4 a1 sa ss swe swex dq t avkh t khax t avkh t khax t avkh t khax g t ghqz t glqx t glqv t khkh t khkl t klkh k, k note: zz = v il write cycle a2 a3 a4 a1 k, k sa ss swe swex dq t avkh t khax t avkh t khax t avkh t khax g d1 d2 d3 d0 t avkh t khax t dvkh t khdx t khkh t khkl t klkh note: zz = v il hm64ylb36514 series rev.0.10, may.15.2003, page 13 of 22 read-write cycle-1 k, k t khkh t khkl t klkh a6 a7 a3 a4 a1 sa t avkh t khax ss t avkh t khax swe t avkh t khax swex t avkh t khax q0 q1 d3 q4 d6 g t klqx t klqv t ghqz t dvkh t khdx t glqv t glqx t khqz dq read read read write dead ( ss control) write t khqv q2 a2 note: zz = v il read-write cycle-2 k, k t khkh t khkl t klkh a6 a7 a3 a4 a1 sa t avkh t khax ss t avkh t khax swe t avkh t khax swex t avkh t khax q0 q1 d3 q4 d6 g t klqx t klqv t khqz t dvkh t khdx t klqv dq read read read write dead ( ss control) write t khqv q2 low fixed a2 a5 t khqz note: g, zz = v il during this period dq pins are in the output state so that the input signal of opposite phase to the outputs must not be applied. hm64ylb36514 series rev.0.10, may.15.2003, page 14 of 22 zz control k, k t khkh t khkl t klkh sa a1 t avkh t khax ss t avkh t khax swex swe t avkh t khax q1 t zzr dq t zze zz sleep active sleep off sleep active hm64ylb36514 series rev.0.10, may.15.2003, page 15 of 22 input capacitance (v dd = 2.5 v, v ddq = 1.5 v, ta = +25 c, f = 1 mhz) parameter symbol min max unit pin name notes input capacitance c in ? 4 pf san, ss , swe , swex 1, 3 clock input capacitance c clk ? 5 pf k, k 1, 2, 3 i/o capacitance c io ? 5 pf dqxn 1, 3 notes: 1. this parameter is sampled and not 100% tested. 2. exclude g 3. connect pins to gnd, except v dd , v ddq , and the measured pin. ac test conditions parameter symbol conditions unit note input and output timing reference levels v ref 0.75 v input signal amplitude v il , v ih 0.25 to 1.25 v input rise / fall time tr, tf 0.5 (10% to 90%) ns clock input timing reference level differential cross point v dif to clock 0.75 v v cm to clock 1.10 v output loading conditions see figure below note: parameters are tested with rq = 250 ? and v ddq = 1.5 v . output loading conditions 50 ? 16.7 ? 16.7 ? 50 ? 5 pf dq 50 ? 16.7 ? 50 ? 5 pf 0.75 v 0.75 v 0.75 v hm64ylb36514 series rev.0.10, may.15.2003, page 16 of 22 boundary scan test access port operations overview in order to perform the interconnect testing of the modules that include this sram, the serial boundary scan test access port (tap) is designed to operate in a manner consistent with ieee standard 1149.1 - 1990. but does not implement all of the functions required for 1149.1 compliance the hm64ylb series contains a tap controller. instruction register, boundary scans register, bypass register and id register. test access port pins symbol i/o name tck test clock tms test mode select tdi test data in tdo test data out note: this device does not have a trst (tap reset) pin. trst is optional in ieee 1149.1. to disable the tap, tck must be connected to v ss . tdo should be left unconnected. to test boundary scan, the zz pin needs to be kept below v ref ? 0.4 v. tap dc operating characteristics (ta = 0 to +85 c) parameter symbol min max notes boundary scan input high voltage v ih 1.4 v 3.6 v boundary scan input low voltage v il ? 0.3 v 0.8 v boundary scan input leakage current i li ? 10 a +10 a 1 boundary scan output low voltage v ol ? 0.2 v 2 boundary scan output high voltage v oh 2.1 v ? 3 boundary scan output leakage current i lo ? 5 a +5 a 4 notes: 1. 0 v in 3.6 v for all logic input pins 2. i ol = 2 ma at v dd = 2.5 v. 3. i oh = ? 2 ma at v dd = 2.5 v. 4. 0 v out v dd , tdo in high-z hm64ylb36514 series rev.0.10, may.15.2003, page 17 of 22 tap ac operating characteristics (ta = 0 to +85 c) parameter symbol min max unit note test clock cycle time t thth 67 ? ns test clock high pulse width t thtl 30 ? ns test clock low pulse width t tlth 30 ? ns test mode select setup t mvth 10 ? ns test mode select hold t thmx 10 ? ns capture setup t cs 10 ? ns 1 capture hold t ch 10 ? ns 1 tdi valid to tck high t dvth 10 ? ns tck high to tdi don ? t care t thdx 10 ? ns tck low to tdo unknown t tlqx 0 ? ns tck low to tdo valid t tlqv ? 20 ns note: 1. t cs + t ch defines the minimum pause in ram i/o pad transitions to assure pad data capture. tap ac test conditions (v dd = 2.5 v) temperature 0 c ta +85 c input timing measurement reference level 1.1 v input pulse levels 0 to 2.5 v input rise/fall time 1.5 ns typical (10% to 90%) output timing measurement reference level 1.25 v test load termination supply voltage (v t ) 1.25 v output load see figure below boundary scan ac test load dut tdo z 0 = 50 ? 50 ? v t hm64ylb36514 series rev.0.10, may.15.2003, page 18 of 22 tap controller timing diagram tck tms tdi tdo ram address t thth t thtl t mvth t thmx t dvth t thdx t tlqv t tlqx t cs t ch t tlth test access port registers register name length symbol note instruction register 3 bits ir [2:0] bypass register 1 bit bp id register 32 bits id [31:0] boundary scan register 70 bits bs [70:1] tap controller instruction set ir2 ir1 ir0 instruction operation 0 0 0 sample-z tristate all data drivers and capture the pad value 0 0 1 idcode 0 1 0 sample-z tristate all data drivers and capture the pad value 0 1 1 bypass 1 0 0 sample 1 0 1 bypass 1 1 0 private do not use. they are reserved for vendor use only 1 1 1 bypass note: this device does not perform extest, intest or the preload portion of the preload command in ieee 1149.1. hm64ylb36514 series rev.0.10, may.15.2003, page 19 of 22 boundary scan order (hm64ylb36514) bit # bump id signal name bit # bump id signal name 1 5r m2 36 3b sa12 2 4p sa0 37 2b sa15 3 4t sa3 38 3a sa13 4 6r sa1 39 3c sa11 5 5t sa2 40 2c sa16 6 7t zz 41 2a sa14 7 6p dqa8 42 2d dqc8 8 7p dqa7 43 1d dqc7 9 6n dqa6 44 2e dqc6 10 7n dqa5 45 1e dqc5 11 6m dqa4 46 2f dqc4 12 6l dqa2 47 2g dqc2 13 7l dqa3 48 1g dqc3 14 6k dqa0 49 2h dqc0 15 7k dqa1 50 1h dqc1 16 5l swea 51 3g swec 17 4l k 52 4d zq 18 4k k 53 4e ss 19 4f g 54 4g nc 20 5g sweb 55 4h nc 21 7h dqb1 56 4m swe 22 6h dqb0 57 3l swed 23 7g dqb3 58 1k dqd1 24 6g dqb2 59 2k dqd0 25 6f dqb4 60 1l dqd3 26 7e dqb5 61 2l dqd2 27 6e dqb6 62 2m dqd4 28 7d dqb7 63 1n dqd5 29 6d dqb8 64 2n dqd6 30 6a sa7 65 1p dqd7 31 6c sa8 66 2p dqd8 32 5c sa4 67 3t sa18 33 5a sa6 68 2r sa10 34 6b sa9 69 4n sa17 35 5b sa5 70 3r m1 hm64ylb36514 series rev.0.10, may.15.2003, page 20 of 22 notes: 1. bit#1 is the first scan bit to exit the chip. 2. the nc pads listed in this table are indeed no connects, but are represented in the boundary scan register by a ? place holder ? . place holder registers are internally connected to v ss . 3. in boundary scan mode, differential input k and k are referenced to each other and must be at the opposite logic levels for the reliable operation. 4. zz must remain v il during boundary scan. 5. in boundary scan mode, zq must be driven to v ddq or v ss supply rail to ensure consistent results. 6. m1 and m2 must be driven to v dd , v ddq or v ss supply rail to ensure consistent results. id register part revision number (31:28) device density and configuration (27:18) vendor definition (17:12) vendor jedec code (11:1) start bit (0) hm64ylb36514 0000 0011100100 000000 00000000111 1 tap controller state diagram 1 111 0 0 00 00 0 0 0 1 11 11 0 1 11 1 10 10 0 0 0 0 1 test-logic- reset run-test/ idle select- dr-scan capture-dr shift-dr exit1-dr pause-dr exit2-dr update-dr capture-ir shift-ir exit1-ir pause-ir exit2-ir update-ir select- ir-scan note: the value adjacent to each state transition in this figure represents the signal present at tms at the time of a rising edge at tck. no matter what the original state of the controller, it will enter test-logic-reset when tms is held high for at least five rising edges of tck. hm64ylb36514 series rev.0.10, may.15.2003, page 21 of 22 package dimensions hm64ylb36514bp series (bp-119e) package code jedec jeita mass (reference value) bp-119e ? ? 1.1 g a 0.20 4 14.00 1.27 1.27 11.08 0.20 c 22.00 18.04 c 0.35 c 0.30 119 0.88 0.06 cab m 0.15 c m a 1 2 3 4 5 6 7 b c d e f g h j k l m n p r t u y 0.69 0.08 2.02 0.22 (0.15) details of the part y b unit: mm preliminary hm64ylb36514 series rev.0.10, may.15.2003, page 22 of 22 keep safety first in your circuit designs! 1. renesas technology corporation puts the maximum effort into making semiconductor products better and more reliable, but ther e is always the possibility that trouble may occur with them. trouble with semiconductors may lead to personal injury, fire or property damage. remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap. notes regarding these materials 1. these materials are intended as a reference to assist our customers in the selection of the renesas technology corporation p roduct best suited to the customer's application; they do not convey any license under any intellectual property rights, or any other rights, belonging to renesas technology corporat ion or a third party. 2. renesas technology corporation assumes no responsibility for any damage, or infringement of any third-party's rights, origin ating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. 3. all information contained in these materials, including product data, diagrams, charts, programs and algorithms represents i nformation on products at the time of publication of these materials, and are subject to change by renesas technology corporation without notice due to product improvements or other reas ons. it is therefore recommended that customers contact renesas technology corporation or an authorized renesas technology corporation product distributor for the latest produ ct information before purchasing a product listed herein. the information described here may contain technical inaccuracies or typographical errors. renesas technology corporation assumes no responsibility for any damage, liability, or other loss rising from these inaccuracie s or errors. please also pay attention to information published by renesas technology corporation by various means, including the renesas te chnology corporation semiconductor home page (http://www.renesas.com). 4. when using any or all of the information contained in these materials, including product data, diagrams, charts, programs, a nd algorithms, please be sure to evaluate all information as a total system before making a final decision on the applicability of the information and products. renesas technology corp oration assumes no responsibility for any damage, liability or other loss resulting from the information contained herein. 5. renesas technology corporation semiconductors are not designed or manufactured for use in a device or system that is used un der circumstances in which human life is potentially at stake. please contact renesas technology corporation or an authorized renesas technology corporation product distributor wh en considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or u ndersea repeater use. 6. the prior written approval of renesas technology corporation is necessary to reprint or reproduce in whole or in part these materials. 7. if these products or technologies are subject to the japanese export control restrictions, they must be exported under a lic ense from the japanese government and cannot be imported into a country other than the approved destination. any diversion or reexport contrary to the export control laws and regulations of japan and/or the country of destination is pro hibited. 8. please contact renesas technology corporation for further details on these materials or the products contained therein. sales strategic planning div. nippon bldg., 2-6-2, ohte-machi, chiyoda-ku, tokyo 100-0004, japan http://www.renesas.com copyright ? 2003. renesas technology corporation, all rights reserved. printed in japan. colophon 0.0 |
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