Preliminary R1WV6416R Series 64Mb Advanced LPSRAM (4M word x 16bit / 8M word x 8bit) REJ03C0368-0001 Preliminary Rev.0.01 2008.03.24 Description The R1WV6416R Series is a family of low voltage 64-Mbit static RAMs organized as 4,194,304-word by 16-bit, fabricated by Renesas’s high-performance 0.15um CMOS and TFT technologies. The R1WV6416R Series is suitable for memory applications where a simple interfacing, battery operating and battery backup are the important design objectives. The R1WV6416R Series is provided in 48-pin thin small outline package [TSOP (I): 12mm x 20mm with pin pitch of 0.5mm], 52-pin micro thin small outline package [µTSOP (II): 10.79mm x 10.49mm with pin pitch of 0.4mm] and 48-ball fine pitch ball grid array [f-BGA] package. It gives the best solution for compaction of mounting area as well as flexibility of wiring pattern of printed circuit boards. Features • • • • • • • • Single 2.7~3.6V power supply Small stand-by current: 8 µA (3.0V, typical) No clocks, No refresh All inputs and outputs are TTL compatible. Easy memory expansion by CS1#, CS2, LB# and UB# Common Data I/O Three-state outputs: OR-tie Capability OE# prevents data contention on the I/O bus Ordering Information Type No. R1WV6416RSA-5S% R1WV6416RSA-7S% R1WV6416RSD-5S% R1WV6416RSD-7S% Access time 55 ns*1 70 ns 55 ns*1 70 ns R1WV6416RBG-5S% R1WV6416RBG-7S% 55 ns*1 70 ns Package 12mm x 20mm 48-pin plastic TSOP (I) (normal-bend type) (48P3R) 350 mil 52-pin plastic μ-TSOP (II) (normal-bend type) (52PTG) f-BGA 0.75mm pitch 48-ball Note1. 55ns parts can be supported under the condition of the input timing limitation toward SRAM on customer’s system. Please contact our sales office in your region, in case of the inquiry for 55ns parts. % R I % - Temperature version; see table below Temperature Range 0 ~ +70 °C -40 ~ +85 °C REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 1 of 16 R1WV6416R Series Preliminary Pin Arrangement A15 1 52 A16 A14 2 51 BYTE# A13 3 50 UB# A12 4 49 Vss A11 5 48 LB# A10 6 47 DQ15/A-1 A9 7 46 DQ7 A8 8 45 DQ14 A19 9 44 DQ6 CS1# 10 43 DQ13 WE# 11 42 DQ5 NC 12 41 DQ12 NC 13 40 DQ4 Vcc 14 39 NC CS2 15 38 DQ11 A21 16 37 DQ3 A20 17 36 DQ10 A18 18 35 DQ2 A17 19 34 DQ9 A7 20 33 DQ1 A6 21 32 DQ8 A5 22 31 DQ0 A4 23 30 OE# A3 24 29 Vss A2 25 28 NC A1 26 27 A0 52-pin μTSOP (II) 1 2 3 4 5 6 A LB# OE# A0 A1 A2 CS2 B DQ15 UB# A3 A4 CS1# DQ0 C DQ13 DQ14 A5 A6 DQ1 DQ2 D Vss DQ12 A17 A7 DQ3 Vcc E Vcc DQ11 A21 A16 DQ4 Vss F DQ10 DQ9 A14 A15 DQ6 DQ5 G DQ8 A19 A12 A13 WE# DQ7 H A18 A8 A9 A10 A11 A20 48-pin f-BGA (TOP VIEW) A15 1 48 A16 A14 2 47 BYTE# A13 3 46 Vss A12 4 45 DQ15/A-1 A11 5 44 DQ7 A10 6 43 DQ14 A9 7 42 DQ6 A8 8 41 DQ13 A19 9 40 DQ5 A20 10 39 DQ12 WE# 11 38 DQ4 CS2 12 37 Vcc A21 13 36 DQ11 UB# 14 35 DQ3 LB# 15 34 DQ10 A18 16 33 DQ2 A17 17 32 DQ9 A7 18 31 DQ1 A6 19 30 DQ8 A5 20 29 DQ0 A4 21 28 OE# A3 22 27 Vss A2 23 26 CS1# A1 24 25 A0 REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 2 of 16 48-pin TSOP (I) R1WV6416R Series Preliminary Pin Description Pin name Vcc Vss A0 to A21 A-1 to A21 DQ0 to DQ15 CS1# CS2 WE# OE# LB# UB# BYTE# NC Function Power supply Ground Address input (word mode) Address input (byte mode) Data input/output Chip select 1 Chip select 2 Write enable Output enable Lower byte enable Upper byte enable Byte control mode enable Non connection Note: BYTE# pin is supported for 48-pin TSOP (I) and 52-pin µTSOP (II) packages. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 3 of 16 R1WV6416R Series Preliminary Block Diagram A0 A1 MEMORY ARRAY ADDRESS ROW BUFFER DECODER 2M-word x16-bit or 4M-word x 8-bit DQ BUFFER A21 DQ1 DQ7 DATA SENSE / WRITE AMPLIFIER DQ0 SELECTOR DQ8 DQ9 COLUMN DECODER DQ BUFFER CLOCK CS2 GENERATOR DQ15 / A -1 CS1# LB# UB# Vcc X8 / x16 CONTROL Vss BYTE# WE# OE# 32Mb SRAM #1 32Mb SRAM #2 Note: BYTE# pin is supported for 48-pin TSOP (I) and 52-pin µTSOP (II) packages. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 4 of 16 R1WV6416R Series Preliminary Operation Table CS1# CS2 BYTE# LB# UB# WE# OE# DQ0~7 DQ8~14 DQ15 Operation H X X X X X X High-Z High-Z High-Z Stand-by X L X X X X X High-Z High-Z High-Z Stand-by X X H H H X X High-Z High-Z High-Z Stand-by L H H L H L X Din High-Z High-Z Write in lower byte L H H L H H L Dout High-Z High-Z Read in lower byte L H H H L L X High-Z Din Din Write in upper byte L H H H L H L High-Z Dout Dout Read in upper byte L H H L L L X Din Din Din Word write L H H L L H L Dout Dout Dout Word read L H H L L H H High-Z High-Z High-Z Output disable L H L L L L X Din High-Z A-1 Byte write L H L L L H L Dout High-Z A-1 Byte read L H L L L H H High-Z High-Z A-1 Output disable Note1. H: VIH L:VIL X: VIH or VIL 2. BYTE# pin is supported for 48-pin TSOP (I) and 52-pin µTSOP (II) packages. 3. When apply BYTE# =“L”, please assign LB#=UB#=“L”. Absolute Maximum Ratings Parameter Power supply voltage relative to Vss Terminal voltage on any pin relative to Vss Power dissipation Operation temperature Storage temperature range Storage temperature range under bias Symbol Vcc VT PT Topr*3 R ver. I ver. Tstg Tbias*3 R ver. Value -0.5 to +4.6 -0.5*1 to Vcc+0.3*2 0.7 0 to +70 -40 to +85 -65 to 150 0 to +70 I ver. Note 1. –2.0V in case of AC (Pulse width ≤30ns) 2. Maximum voltage is +4.6V. 3. Ambient temperature range depends on R/I-version. Please see table on page 1. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 5 of 16 -40 to +85 unit V V W °C °C °C °C °C R1WV6416R Series Preliminary Recommended Operating Conditions Parameter Supply voltage Input high voltage Input low voltage Ambient temperature range Symbol Min. Typ. Max. Unit Vcc Vss VIH VIL 2.7 0 2.4 -0.2 3.0 0 - 3.6 0 0.4 V V V V 0 - +70 °C 1 2 °C 2 R ver. Vcc+0.2 Ta I ver. -40 +85 Note 1. –2.0V in case of AC (Pulse width ≤ 30ns) 2. Ambient temperature range depends on R/I-version. Please see table on page 1. Note DC Characteristics Parameter Input leakage current Output leakage current Symbol Min. Typ. Max. Unit | ILI | - - 1 μA | ILO | - - 1 μA ICC1 - 45*1 60 mA ICC2 - 5*1 10 mA ISB - 0.1*1 0.3 mA - 8*1 24 μA - 14*2 48 μA - - 100 μA - - 160 μA VOH 2.4 - - V VOL - - 0.4 V Average operating current Standby current Standby current ISB1 Output high voltage Output low voltage Test conditions*3 Vin = Vss to Vcc BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V CS1# =VIH or CS2 =VIL or OE# =VIH or WE# =VIL or LB# = UB# =VIH, VI/O =Vss to Vcc Min. cycle, duty =100%, II/O = 0mA BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V CS1# =VIL, CS2 =VIH, Others = VIH/VIL Cycle =1μs, duty =100%, II/O = 0mA BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V CS1# ≤ 0.2V, CS2 ≥ VCC-0.2V, VIH ≥ VCC-0.2V, VIL ≤ 0.2V BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V CS2 =VIH Vin ≥ 0V ~+25°C BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V ~+40°C (1) 0V ≤ CS2 ≤ 0.2V or (2) CS1# ≥ VCC-0.2V, CS2 ≥ VCC-0.2V or ~+70°C (3) LB# = UB# ≥ VCC-0.2V, CS1# ≤ 0.2V, ~+85°C CS2 ≥ VCC-0.2V BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V IOH = -0.5mA BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V IOL = 2mA Note 1. Typical parameter indicates the value for the center of distribution at 3.0V (Ta= 25ºC), and not 100% tested. 2. Typical parameter indicates the value for the center of distribution at 3.0V (Ta= 40ºC), and not 100% tested. 3. BYTE# pin is supported for 48-pin TSOP (I) and 52-pin µTSOP (II) packages. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 6 of 16 R1WV6416R Series Preliminary Capacitance (Ta =25°C, f =1MHz) Parameter Symbol Min. Typ. Input capacitance C in Input / output capacitance C I/O Note1.This parameter is sampled and not 100% tested. Max. 20 20 Unit pF pF Test conditions Vin =0V V I/O =0V AC Characteristics Test Conditions (Vcc = 2.7V ~ 3.6V, Ta = 0 ~ +70°C / -40 ~ +85°C*1) • • • • Input pulse levels: VIL = 0.4V, VIH = 2.4V Input rise and fall time: 5ns Input and output timing reference level: 1.4V Output load: See figures (Including scope and jig) 1.4V RL = 500 ohm DQ CL = 30 pF Note1. Ambient temperature range depends on R/I-version. Please see table on page 1. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 7 of 16 Note 1 1 R1WV6416R Series Preliminary Read Cycle R1WV6416R**-5S Parameter Read cycle time Address access time Chip select access time Output enable to output valid Output hold from address change LB#, UB# access time Chip select to output in low-Z LB#, UB# enable to low-Z Output enable to output in low-Z Chip deselect to output in high-Z LB#, UB# disable to high-Z Output disable to output in high-Z Symbol tRC tAA tACS1 tACS2 tOE tOH tBA tCLZ1 tCLZ2 tBLZ tOLZ tCHZ1 tCHZ2 tBHZ tOHZ REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 8 of 16 (Note 0) Min. 55 10 10 10 5 5 0 0 0 0 Max. 70 55 55 25 55 20 20 20 20 R1WV6416R**-7S Min. 70 10 10 10 5 5 0 0 0 0 Max. 70 70 70 35 70 25 25 25 25 Unit Note ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 2,3 2,3 2,3 2,3 1,2,3 1,2,3 1,2,3 1,2,3 R1WV6416R Series Preliminary Write Cycle R1WV6416R**-5S Parameter Write cycle time Address valid to end of write Chip select to end of write Write pulse width LB#, UB# valid to end of write Address setup time Write recovery time Data to write time overlap Data hold from write time Output enable from end of write Output disable to output in high-Z Write to output in high-Z Symbol tWC tAW tCW tWP tBW tAS tWR tDW tDH tOW tOHZ tWHZ (Note 0) Min. 55 50 50 40 50 0 0 25 0 5 0 0 Max. 20 20 R1WV6416R**-7S Min. 70 65 65 55 65 0 0 35 0 5 0 0 Max. 25 25 Unit ns ns ns ns ns ns ns ns ns ns ns ns Note 5 4 6 7 2 1,2 1,2 Note0. 55ns parts can be supported under the condition of the input timing limitation toward SRAM on customer’s system. Please contact our sales office in your region, in case of the inquiry for 55ns parts. In case of tAA =70ns, tRC =70ns. 1. tCHZ, tOHZ, tWHZ and tBHZ are defined as the time at which the outputs achieve the open circuit conditions and are not referred to output voltage levels. 2. This parameter is sampled and not 100% tested. 3. At any given temperature and voltage condition, tHZ max is less than tLZ min both for a given device and from device to device. 4. A write occurs during the overlap of a low CS1#, a high CS2, a low WE# and a low LB# or a low UB#. A write begins at the latest transition among CS1# going low, CS2 going high, WE# going low and LB# going low or UB# going low . A write ends at the earliest transition among CS1# going high, CS2 going low, WE# going high and LB# going high or UB# going high. tWP is measured from the beginning of write to the end of write. 5. tCW is measured from the later of CS1# going low or CS2 going high to end of write. 6. tAS is measured the address valid to the beginning of write. 7. tWR is measured from the earliest of CS1# or WE# going high or CS2 going low to the end of write cycle. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 9 of 16 R1WV6416R Series Preliminary BYTE# Timing Conditions Parameter Byte setup time Byte recovery time Symbol tBS tBR R1WV6416R**-5S Min. 5 5 Max. - R1WV6416R**-7S Min. 5 5 BYTE# Timing Waveforms CS1# CS2 tBS BYTE# REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 10 of 16 tBR Max. - Unit ms ms Note R1WV6416R Series Preliminary Timing Waveforms Read Cycle*1 tRC A0~21 (Word Mode) A -1~21 tBA LB#,UB# tBLZ tBHZ tACS1 CS1# tCLZ1 CS2 tCHZ1 tACS2 tCLZ2 WE# WE# = “H” level VIL tOE tOLZ tOHZ High impedance (Word Mode) DQ0~7 (Byte Mode) Note1. BYTE# ≥ Vcc – 0.2V or BYTE# ≤ 0.2V REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 11 of 16 tCHZ2 VIH OE# DQ0~15 tOH tAA (Byte Mode) Valid Data R1WV6416R Series Preliminary Write Cycle (1)*1 (WE# CLOCK) tWC A0~21 (Word Mode) A -1~21 tOH (Byte Mode) tBW LB#,UB# tCW CS1# tCW CS2 tAW tAS tWP tWR WE# OE# tWHZ tOLZ tOHZ tOW DQ0~15 (Word Mode) DQ0~7 (Byte Mode) Note1. BYTE# ≥ Vcc – 0.2V or BYTE# ≤ 0.2V REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 12 of 16 Valid Data tDW tDH R1WV6416R Series Preliminary Write Cycle (2)*1 (CS1#, CS2 CLOCK) tWC A0~21 (Word Mode) A -1~21 tAW (Byte Mode) tBW LB#,UB# tAS tCW tWR tAS tCW tWR CS1# CS2 tWP WE# OE# OE# = “H” level VIH VIL tDW tDH DQ0~15 (Word Mode) DQ0~7 (Byte Mode) Note1. BYTE# ≥ Vcc – 0.2V or BYTE# ≤ 0.2V REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 13 of 16 Valid Data R1WV6416R Series Preliminary Write Cycle (3)*1 (LB#, UB# CLOCK) tWC A0~21 (Word Mode) A -1~21 tAW (Byte Mode) tAS tBW tWR LB#,UB# tCW CS1# tCW CS2 tWP WE# OE# OE# = “H” level VIH VIL tDW tDH DQ0~15 (Word Mode) DQ0~7 (Byte Mode) Note1. BYTE# ≥ Vcc – 0.2V or BYTE# ≤ 0.2V REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 14 of 16 Valid Data R1WV6416R Series Preliminary Low Vcc Data Retention Characteristics Parameter VCC for data retention Data retention current Chip select to data retention time Operation recovery time Symbol VDR Min. Typ Max. Unit 2.0 - 3.6 V - 8*1 24 μA - 14*2 48 μA - - 100 μA - - 160 μA tCDR 0 - - ns tR 5 - - ms ICCDR Test conditions*3,4 Vin ≥ 0V BYTE# ≥ Vcc -0.2V or BYTE# ≤ 0.2V (1) 0V ≤ CS2 ≤ 0.2V or (2) CS1# ≥ VCC-0.2V, CS2 ≥ VCC-0.2V or (3) LB# = UB# ≥ VCC-0.2V, CS1# ≤ 0.2V, CS2 ≥ VCC-0.2V Vin ≥ 0V ~+25°C BYTE# ≥ Vcc -0.2V or BYTE# ≤0.2V ~+40°C (1) 0V ≤ CS2 ≤ 0.2V or (2) CS1# ≥ VCC-0.2V, CS2 ≥ VCC-0.2V or ~+70°C (3) LB# = UB# ≥ VCC-0.2V, CS1# ≤ 0.2V, ~+85°C CS2 ≥ VCC-0.2V See retention waveform. Note 1. Typical parameter indicates the value for the center of distribution at 3.0V (Ta= 25ºC), and not 100% tested. 2. Typical parameter indicates the value for the center of distribution at 3.0V (Ta= 40ºC), and not 100% tested. 3. BYTE# pin is supported for 48-pin TSOP (I) and 52-pin µTSOP (II) packages. 4. CS2 also controls address buffer, WE# buffer ,CS1# buffer ,OE# buffer ,LB# ,UB# buffer and Din buffer. If CS2 controls data retention mode, Vin levels (address, WE# ,OE#,CS1#,LB#,UB#,I/O) can be in the high impedance state. If CS1# controls data retention mode, CS2 must be CS2 ≥ Vcc-0.2V or0V ≤ CS2 ≤ 0.2V. The other input levels (address, WE# ,OE#,CS1#,LB#,UB#,I/O) can be in the high impedance state. REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 15 of 16 R1WV6416R Series Preliminary Low Vcc Data Retention Timing Waveforms*1 (1) CS1# Controlled Vcc 2.7V tCDR 2.7V tR VDR 2.2V 2.2V CS1# ≥ Vcc - 0.2V CS1# (2) CS2 Controlled Vcc 2.7V tCDR CS2 2.7V tR VDR 0.6V 0.6V 0V ≤ CS2 ≤ 0.2V (3) LB#, UB# Controlled Vcc 2.7V tCDR VDR 2.2V LB#, UB# LB#, UB# ≥ Vcc - 0.2V Note1. BYTE# ≥ Vcc – 0.2V or BYTE# ≤ 0.2V REJ03C0368-0001, Rev.0.01, 2008.03.24 Page 16 of 16 2.7V tR 2.2V Revision History Rev. Date Page 0.01 Mar.24, 2008 - R1WV6416R Data Sheet Contents pf Revision Description Initial issue: Preliminary Data Sheet Sales Strategic Planning Div. Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan Notes: 1. This document is provided for reference purposes only so that Renesas customers may select the appropriate Renesas products for their use. Renesas neither makes warranties or representations with respect to the accuracy or completeness of the information contained in this document nor grants any license to any intellectual property rights or any other rights of Renesas or any third party with respect to the information in this document. 2. Renesas shall have no liability for damages or infringement of any intellectual property or other rights arising out of the use of any information in this document, including, but not limited to, product data, diagrams, charts, programs, algorithms, and application circuit examples. 3. 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