AS4C4M4F0 AS4C4M4F1 ® 5V 4M×4 CMOS DRAM (Fast Page mode) Features • Organization: 4,194,304 words × 4 bits • High speed • TTL-compatible, three-state I/O • JEDEC standard package - 50/60 ns RAS access time - 25/30 ns column address access time - 12/15 ns CAS access time - 300 mil, 24/26-pin SOJ - 300 mil, 24/26-pin TSOP • Latch-up current ≥ 200 mA • ESD protection ≥ 2000 mV • Industrial and commercial temperature available • Low power consumption - Active: 908 mW max - Standby: 5.5 mW max, CMOS I/O • Fast page mode • Refresh - 4096 refresh cycles, 64 ms refresh interval for AS4C4M4F0 - 2048 refresh cycles, 32 ms refresh interval for AS4C4M4F1 - RAS-only or CAS-before-RAS refresh or self-refresh Pin arrangement Pin designation A10 A0 A1 A2 A3 VCC 1 2 3 4 5 6 8 9 10 11 12 13 TSOP 26 25 24 23 22 21 GND I/O3 I/O2 CAS OE A9 19 18 17 16 15 14 A8 A7 A6 A5 A4 GND VCC I/O0 I/O1 WE RAS *NC/A11 A10 A0 A1 A2 A3 VCC 1 2 3 4 5 6 8 9 10 11 12 13 AS4C4M4F0 VCC I/O0 I/O1 WE RAS *NC/A11 AS4C4M4F0 SOJ 26 25 24 23 22 21 GND I/O3 I/O2 CAS OE A9 19 18 17 16 15 14 A8 A7 A6 A5 A4 GND Pin(s) Description A0 to A11 Address inputs RAS Row address strobe CAS Column address strobe WE Write enable I/O0 to I/O3 Input/output OE Output enable VCC Power GND Ground *NC on 2K refresh version; A11 on 4K refresh version Selection guide Symbol AS4C4M4F0-50 AS4C4M4F1-50 AS4C4M4F0-60 AS4C4M4F1-60 Unit Maximum RAS access time tRAC 50 60 ns Maximum column address access time tCAA 25 30 ns Maximum CAS access time tCAC 12 15 ns Maximum output enable (OE) access time tOEA 13 15 ns Minimum read or write cycle time tRC 85 100 ns Minimum fast page mode cycle time tPC 25 30 ns Maximum operating current ICC1 135 120 mA Maximum CMOS standby current ICC5 1.0 1.0 mA 4/11/01; v.0.9 Alliance Semiconductor P. 1 of 18 Copyright © Alliance Semiconductor. All rights reserved. AS4C4M4F0 AS4C4M4F1 ® Functional description The AS4C4M4F0 and AS4C4M4F1 are high performance 16-megabit CMOS Dynamic Random Access Memory (DRAM) devices organized as 4,194,304 words × 4 bits. The devices are fabricated using advanced CMOS technology and innovative design techniques resulting in high speed, extremely low power and wide operating margins at component and system levels. The Alliance 16Mb DRAM family is optimized for use as main memory in PC, workstation, router and switch applications. These devices feature a high speed page mode operation where read and write operations within a single row (or page) can be executed at very high speed by toggling column addresses within that row. Row and column addresses are alternately latched into input buffers using the falling edge of RAS and CAS inputs respectively. Also, RAS is used to make the column address latch transparent, enabling application of column addresses prior to CAS assertion. Refresh on the 4096 address combinations of A0 to A11 must be performed every 64 ms using: • RAS-only refresh: RAS is asserted while CAS is held high. Each of the 4096 rows must be strobed. Outputs remain high impedence. • Hidden refresh: CAS is held low while RAS is toggled. Refresh address is generated internally. Outputs remain low impedence with previous valid data. • CAS-before-RAS refresh (CBR): CAS is asserted prior to RAS. Refresh address is generated internally. Outputs are high-impedence (OE and WE are don't care). • Normal read or write cycles refresh the row being accessed. • Self-refresh cycles Refresh on the 2048 address combinations of A0 to A10 must be performed every 32 ms using: • RAS-only refresh: RAS is asserted while CAS is held high. Each of the 2048 rows must be strobed. Outputs remain high impedence. • Hidden refresh: CAS is held low while RAS is toggled. Refresh address is generated internally. Outputs remain low impedence with previous valid data. • CAS-before-RAS refresh (CBR): CAS is asserted prior to RAS. Refresh address is generated internally. Outputs are high-impedence (OE and WE are don't care). • Normal read or write cycles refresh the row being accessed. • Self-refresh cycles The AS4C4M4F0 and AS4C4M4F1 are available in the standard 24/26-pin plastic SOJ and 24/26-pin plastic TSOP packages. The AS4C4M4F0 and AS4C4M4F1 operate with a single power supply of 5V ± 0.5V and provide TTL compatible inputs and outputs. Refresh controller Logic block diagram for 4K refresh RAS CAS WE 4/11/01; v.0.9 RAS clock generator CAS clock generator WE clock generator A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 Column decoder Sense amp Data I/O buffers I/O0 to I/O3 OE Row decoder GND Address buffers VCC 4096 × 1024 × 4 Array (16,777,216) Alliance Semiconductor P. 2 of 18 AS4C4M4F0 AS4C4M4F1 ® Refresh controller Logic block diagram for 2K refresh GND CAS WE RAS clock generator CAS clock generator WE clock generator A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 Sense amp I/O0 to I/O3 OE Address buffers RAS Data I/O buffers Column decoder Row decoder VCC 2048 × 2048 × 4 Array (16,777,216) Substrate bias generator Recommended operating conditions Parameter Supply voltage Input voltage Ambient operating temperature †V IL Symbol Min Nominal Max Unit VCC 4.5 5.0 5.5 V GND 0.0 0.0 0.0 V VIH 2.4 – VCC V – 0.8 V 0 – 70 -40 – 85 VIL Commercial Industrial TA –0.5 † °C min -3.0V for pulse widths less than 5 ns. Recommended operating conditions apply throughout this document unlesss otherwise specified. 4/11/01; v.0.9 Alliance Semiconductor P. 3 of 18 AS4C4M4F0 AS4C4M4F1 ® Absolute maximum ratings Parameter Symbol Min Max Unit Input voltage Vin -1.0 +7.0 V Input voltage (DQs) VDQ -1.0 VCC + 0.5 V Power supply voltage VCC -1.0 +7.0 V Storage temperature (plastic) TSTG -55 +150 °C Soldering temperature × time TSOLDER – 260 × 10 o Power dissipation PD – 1 W Short circuit output current Iout – 50 mA C × sec DC electrical characteristics -50 Parameter Symbol Test conditions Input leakage current IIL Output leakage current -60 Min Max Min Max Unit 0V ≤ Vin ≤ +5.5V, Pins not under test = 0V -5 +5 -5 +5 µA IOL DOUT disabled, 0V ≤ Vout ≤ +5.5V -5 +5 -5 +5 µA Operating power supply current ICC1 RAS, CAS Address cycling; tRC=min – 135 – 120 mA TTL standby power supply current ICC2 RAS = CAS ≥ VIH – 2.0 – 2.0 mA Average power supply current, RAS refresh mode or CBR ICC3 RAS cycling, CAS ≥ VIH, tRC = min of RAS low after XCAS low. – 120 – 110 mA 1 Fast page mode average power supply current ICC4 RAS = VIL, CAS, address cycling: tHPC = min – 130 – 120 mA 1, 2 CMOS standby power supply current ICC5 RAS = CAS = VCC - 0.2V – 1.0 – 1.0 mA VOH IOUT = -5.0 mA 2.4 – 2.4 – V VOL IOUT = 4.2 mA – 0.4 – 0.4 V ICC6 RAS, CAS cycling, tRC = min – 120 – 110 mA ICC7 RAS = UCAS = LCAS ≤ 0.2V, WE = OE ≥ VCC - 0.2V, all other inputs at 0.2V or VCC - 0.2V – 0.6 – 0.6 mA Output voltage CAS before RAS refresh current Self refresh current 4/11/01; v.0.9 Alliance Semiconductor Notes 1,2 P. 4 of 18 AS4C4M4F0 AS4C4M4F1 ® AC parameters common to all waveforms -50 -60 Symbol Parameter Min Max Min Max Unit Notes tRC Random read or write cycle time 80 – 100 – ns tRP RAS precharge time 30 – 40 – ns tRAS RAS pulse width 50 10K 60 10K ns tCAS CAS pulse width 8 10K 10 10K ns tRCD RAS to CAS delay time 15 35 15 43 ns 6 tRAD RAS to column address delay time 12 25 12 30 ns 7 tRSH CAS to RAS hold time 10 – 10 – ns tCSH RAS to CAS hold time 40 – 50 – ns tCRP CAS to RAS precharge time 5 – 5 – ns tASR Row address setup time 0 – 0 – ns tRAH Row address hold time 8 – 10 – ns tT Transition time (rise and fall) 1 50 1 50 ns 4,5 tREF Refresh period – 64 – 64 ms 3 tCP CAS precharge time 8 – 10 – ns tRAL Column address to RAS lead time 25 – 30 – ns tASC Column address setup time 0 – 0 – ns tCAH Column address hold time 8 10 – ns Read cycle -50 Symbol Parameter tRAC -60 Min Max Min Max Unit Access time from RAS – 50 – 60 ns 6 tCAC Access time from CAS – 12 – 15 ns 6,13 tAA Access time from address – 25 – 30 ns 7,13 tRCS Read command setup time 0 – 0 – ns tRCH Read command hold time to CAS 0 – 0 – ns 9 tRRH Read command hold time to RAS 0 – 0 – ns 9 4/11/01; v.0.9 Alliance Semiconductor Notes P. 5 of 18 AS4C4M4F0 AS4C4M4F1 ® Write cycle -50 Symbol Parameter tWCS -60 Min Max Min Max Unit Notes Write command setup time 0 – 0 – ns 11 tWCH Write command hold time 10 – 10 – ns 11 tWP Write command pulse width 10 – 10 – ns tRWL Write command to RAS lead time 10 – 10 – ns tCWL Write command to CAS lead time 8 – 10 – ns tDS Data-in setup time 0 – 0 – ns 12 tDH Data-in hold time 8 – 10 – ns 12 Read-modify-write cycle -50 -60 Symbol Parameter Min Max Min Max Unit Notes tRWC Read-write cycle time 113 – 135 – ns tRWD RAS to WE delay time 67 – 77 – ns 11 tCWD CAS to WE delay time 32 – 35 – ns 11 tAWD Column address to WE delay time 42 – 47 – ns 11 Refresh cycle -50 Symbol Parameter tCSR -60 Min Max Min Max Unit CAS setup time (CAS-before-RAS) 5 – 5 – ns 3 tCHR CAS hold time (CAS-before-RAS) 8 – 10 – ns 3 tRPC RAS precharge to CAS hold time 0 – 0 – ns tCPT CAS precharge time (CBR counter test) 10 10 – ns 4/11/01; v.0.9 Alliance Semiconductor Notes P. 6 of 18 AS4C4M4F0 AS4C4M4F1 ® Fast page mode cycle -50 Symbol Parameter tCPA -60 Min Max Min Max Access time from CAS precharge – 28 – 35 tRASP RAS pulse width 50 100K 60 100K tPC Read-write cycle time 30 – 35 – tCP CAS precharge time (fast page) 10 – 10 – tPCM Fast page mode RMW cycle 80 – 85 – tCRW Page mode CAS pulse width (RMW) 12 – 15 – Unit Notes 13 Output enable -50 Symbol Parameter tCLZ -60 Min Max Min Max Unit Notes CAS to output in Low Z 0 – 0 – ns tROH RAS hold time referenced to OE 8 – 10 – ns tOEA OE access time – 13 – 15 ns tOED OE to data delay 13 – 15 – ns tOEZ Output buffer turnoff delay from OE 0 13 0 15 ns tOEH OE command hold time 10 – 10 – ns tOLZ OE to output in Low Z 0 – 0 – ns tOFF Output buffer turn-off time 0 13 0 15 ns 8,10 Notes 8 8 Self refresh cycle -50 -60 Std Symbol Parameter Min Max Min Max Unit tRASS RAS pulse width (CBR self refresh) 100 – 100 – µs tRPS RAS precharge time (CBR self refresh) 90 – 105 – ns tCHS CAS hold time (CBR self refresh) 8 – 10 – ns 4/11/01; v.0.9 Alliance Semiconductor P. 7 of 18 AS4C4M4F0 AS4C4M4F1 ® Notes 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 ICC1, ICC3, ICC4, and ICC6 are dependent on frequency. ICC1 and ICC4 depend on output loading. Specified values are obtained with the output open. An initial pause of 200 µs is required after power-up followed by any 8 RAS cycles before proper device operation is achieved. In the case of an internal refresh counter, a minimum of 8 CAS-before-RAS initialization cycles instead of 8 RAS cycles are required. 8 initialization cycles are required after extended periods of bias without clocks (greater than 8 ms). AC Characteristics assume tT = 2 ns. All AC parameters are measured with a load equivalent to two TTL loads and 100 pF, VIL (min) ≥ GND and VIH (max) ≤ VCC. VIH (min) and VIL (max) are reference levels for measuring timing of input signals. Transition times are measured between VIH and VIL. Operation within the tRCD (max) limit insures that tRAC (max) can be met. tRCD (max) is specified as a reference point only. If tRCD is greater than the specified tRCD (max) limit, then access time is controlled exclusively by tCAC. Operation within the tRAD (max) limit insures that tRAC (max) can be met. tRAD (max) is specified as a reference point only. If tRAD is greater than the specified tRAD (max) limit, then access time is controlled exclusively by tAA. Assumes three state test load (5 pF and a 380 Ω Thevenin equivalent). Either tRCH or tRRH must be satisfied for a read cycle. tOFF (max) defines the time at which the output achieves the open circuit condition; it is not referenced to output voltage levels. tOFF is referenced from rising edge of RAS or CAS, whichever occurs last. tWCS, tWCH, tRWD, tCWD and tAWD are not restrictive operating parameters. They are included in the datasheet as electrical characteristics only. If tWS ≥ tWS (min) and tWH ≥ tWH (min), the cycle is an early write cycle and data out pins will remain open circuit, high impedance, throughout the cycle. If tRWD ≥ tRWD (min), tCWD ≥ tCWD (min) and tAWD ≥ tAWD (min), the cycle is a read-write cycle and the data out will contain data read from the selected cell. If neither of the above conditions is satisfied, the condition of the data out at access time is indeterminate. These parameters are referenced to CAS leading edge in early write cycles and to WE leading edge in read-write cycles. Access time is determined by the longest of tCAA or tCAC or tCPA tASC ≥ tCP to achieve tPC (min) and tCPA (max) values. These parameters are sampled and not 100% tested. These characteristics apply to AS4C4M4F0 5V devices. AC test conditions - Access times are measured with output reference levels of VOH = 2.4V and VOL = 0.4V, VIH = 2.4V and VIL = 0.8V - Input rise and fall times: 2 ns +5V +3.3V R1 = 828Ω Dout 100 pF* R2 = 295Ω R1 = 828Ω *including scope and jig capacitance GND Figure A: Equivalent output load (AS4C4M4E0) Dout 50 pF* R2 = 295Ω *including scope and jig capacitance GND Figure B: Equivalent output load (AS4LC4M4E0) Key to switching waveforms Rising input 4/11/01; v.0.9 Falling input Alliance Semiconductor Undefined output/don’t care P. 8 of 18 AS4C4M4F0 AS4C4M4F1 ® Read waveform tRC tRAS tRCD tRSH tRP RAS tCSH tCRP tCAH tCAS tASC tRCS CAS tRAD Address tRAL tRAH tASR Row address Column address tRRH tRCH WE tROH tROH tWEZ OE tOEZ tRAC tAA tOFF (see note 11) tOEA tCAC tREZ tCLZ DQ Data out tOLZ Early write waveform tRC tRAS tRP RAS tCSH tRSH tCRP tRCD tCAS CAS tRAD tRAL tASC tASR Address tRAH tCAH Row address Column address tCWL tRWL tWP tWCS tWCH WE OE tDS DQ 4/11/01; v.0.9 tDH Data in Alliance Semiconductor P. 9 of 18 AS4C4M4F0 AS4C4M4F1 ® Write waveform OE controlled tRC tRAS tRP RAS tCSH tCRP tRSH tCAS tRCD CAS tRAL tRAD tRAH tASR tASC tCAH Row address Address Column address tRWL tCWL tWP WE tOEH OE tDS tOED tDH Data in DQ Read-modify-write waveform tRWC tRAS tRP RAS tCAS tCRP tRCD tRSH tCSH CAS tAR tRAL tRAD tRAH tASR Address tASC tCAH Row address Column address tRWD tRWL tAWD tRCS WE tCWL tCWD tOEA tOEZ tWP tOED OE tRAC tAA tCAC tCLZ Data out DQ tDS tDH Data in tOLZ 4/11/01; v.0.9 Alliance Semiconductor P. 10 of 18 AS4C4M4F0 AS4C4M4F1 ® Fast page mode read waveform tRASP tRP RAS tCSH tCRP tRSH tRCD tCAS tCP tPC CAS tAR tRAD tASR tRAL tASC tRAH Address Column Row tRCS tCAH Column Column tRCS tRCH tRRH tRCH WE tOEA tOEA OE tRAC tOEZ tCLZ tCAP tOFF tAA I/O tCAC Data out Data out Data out Fast page mode byte write waveform tRASP tRP RAS tPCM tCSH tRCD CAS tCAS tCP tCRP tRAD tASR tRAL tRAH tCAH Address Row tCAH Column Column tRWD tRCS tCAH Column tCWL tCWD tRWL tCWD tCWD tAWD tAWD tCWL tWP WE tOEA tOEZ tOED tOEA OE tAA tRAC I/O 4/11/01; v.0.9 tDH tCAP tCLZ tDS tCLZ tCLZ tCAC tCAC tCAC tDS Data in Data out Data in Data out Alliance Semiconductor Data in Data out P. 11 of 18 AS4C4M4F0 AS4C4M4F1 ® Fast page mode early write waveform tRASP tRAH tRWL RAS tCRP tRCD tPC tCSH tCAH tASC tCAS tCP tWCS tRSH CAS tRAL tAR tASR Address tRAD Row Column Column Column tCWL tWP tWCH tOEH WE OE tHDR tOED tDH tDS I/O Data In Data in Data in CAS before RAS refresh waveform WE = VIH tRC tRP tRAS RAS tRPC tCHR tCP tCSR CAS OPEN DQ RAS only refresh waveform WE = OE = VIH or VIL tRC tRAS tRP RAS tCRP tRPC CAS tASR Address 4/11/01; v.0.9 tRAH Row address Alliance Semiconductor P. 12 of 18 AS4C4M4F0 AS4C4M4F1 ® Hidden refresh waveform (read) tRC tRC tRAS tRP tRAS tRP RAS tCRP tCHR tRCD tRSH tCRP CAS tAR tRAD tCAH tRAH tASC tASR Row Address Col address tRCS tRRH WE tOEA OE tRAC tOFF tAA tCAC tCLZ tOEZ Data out DQ Hidden refresh waveform (write) tRC tRAS tRP RAS tCRP tRCD tRSH tCHR CAS tAR tRAD tRAL tRAH tASR Address tASC tCAH Row address Col address tRWL tWCR tWP tWCS tWCH WE tDS tDH tDHR DQ Data in OE 4/11/01; v.0.9 Alliance Semiconductor P. 13 of 18 AS4C4M4F0 AS4C4M4F1 ® CAS before RAS refresh counter test waveform tRAS tRSH tRP RAS CAS tCSR tCHR tCPT tCAS tRAL tASC tCAH Address Col address tAA tCAC tCLZ Read cycle DQ tOFF tOEZ Data out tRRH tRCH tRCS WE tROH tOEA OE tRWL tCWL tWP tWCH Write cycle tWCS WE tDH tDS DQ Data in OE tRWL tWP tRCS tCWD tAWD tCWL Read-Write cycle WE tOEA tOED OE t AA tCLZ tCAC DQ 4/11/01; v.0.9 tDH tOEZ tDS Data out Alliance Semiconductor Data in P. 14 of 18 AS4C4M4F0 AS4C4M4F1 ® CAS-before-RAS self refresh cycle tRP tRASS tRPS RAS tRPC tRPC tCP tCHS tCSR UCAS, LCAS tCEZ DQ Typical DC and AC characteristics 1.5 1.2 1.1 1.0 0.9 0.8 4.0 170 4.5 5.0 5.5 Supply voltage (V) Typical supply current ICC vs. supply voltage VCC 1.2 1.1 1.0 0.9 150 -50 140 -60 130 -70 120 110 150 140 130 4/11/01; v.0.9 6.0 -60 60 -50 50 30 50 Typical supply current ICC vs. ambient temperature Ta 100 150 200 Load capacitance (pF) 250 Typical power-on current IPO vs. cycle rate 1/tRC 35 30 -50 -60 -70 120 100 –55 -70 70 –10 35 80 125 Ambient temperature (°C) 110 4.5 5.0 5.5 Supply voltage (V) 80 40 160 Supply current (mA) Supply current (mA) 90 1.3 170 160 100 4.0 1.4 0.8 –55 6.0 Typical access time tRAC vs. load capacitance CL 100 Power-on current (mA) 1.3 Ta = 25°C Normalized access time tRAC vs. ambient temperature Ta Typical access time 1.4 Normalized access time Normalized access time 1.5 Normalized access time tRAC vs. supply voltage VCC 25 20 15 10 5 0.0 –10 35 80 125 Ambient temperature (°C) Alliance Semiconductor 2 4 6 8 Cycle rate (MHz) 10 P. 15 of 18 AS4C4M4F0 AS4C4M4F1 ® Typical refresh current ICC3 vs. supply voltage VCC 160 140 120 -50 100 -60 -70 Refresh current (mA) 80 60 20 4.0 4.5 5.0 5.5 Supply voltage (V) Typical TTL stand-by current ICC2 vs. ambient temperature Ta 60 2.5 2.0 1.5 1.0 0.5 0.0 0 120 100 -50 80 -60 -70 60 40 20 0.0 0 20 40 60 80 Ambient temperature (°C) 4/11/01; v.0.9 Hyper page mode current (mA) Typical fast page mode current ICC4 vs. ambient temperature Ta 1.5 1.0 0 4.0 70 60 50 40 30 20 10 140 2.0 20 40 60 80 Ambient temperature (°C) Typical output sink current IOL vs. output voltage VOL 0.0 0.0 20 40 60 80 Ambient temperature (°C) 2.5 0.5 70 Output sink current (mA) Stand-by current (mA) 80 20 0.0 6.0 3.0 Hyper page mode current (mA) 100 40 40 140 120 Typical TTL stand-by current ICC2 vs. supply voltage VCC 3.0 -50 -60 -70 Output source current (mA) Refresh current (mA) 140 3.5 3.5 Stand-by current (mA) 160 Typical refresh current ICC3 vs. Ambient temperature Ta 4.5 5.0 5.5 Supply voltage (V) 6.0 Typical output source current IOH vs. output voltage VOH 60 50 40 30 20 10 0.0 0.5 1.0 1.5 Output voltage (V) 2.0 0.0 1.0 2.0 3.0 Output voltage (V) 4.0 Typical fast page mode current ICC4 vs. supply voltage VCC 120 100 80 -50 -60 -70 60 40 20 0.0 4.0 4.5 5.0 5.5 Supply voltage (V) Alliance Semiconductor 6.0 P. 16 of 18 AS4C4M4F0 AS4C4M4F1 ® Capacitance 15 ƒ = 1 MHz, Ta = Room temperature Parameter Input capacitance DQ capacitance Symbol Signals Test conditions Max Unit CIN1 A0 to A9 Vin = 0V 5 pF CIN2 RAS, UCAS, LCAS, WE, OE Vin = 0V 7 pF CDQ DQ0 to DQ15 Vin = Vout = 0V 7 pF AS4C4M4F0 ordering information Package \ RAS access time 50 ns 60 ns Plastic SOJ, 300 mil, 24/26-pin 5V AS4C4M4F0-50JC AS4C4M4F0-50JI AS4C4M4F0-60JC AS4C4M4F0-60JI Plastic TSOP, 300 mil, 24/26-pin 5V AS4C4M4F0-50TC AS4C4M4F0-50TI AS4C4M4F0-60TC AS4C4M4F0-60TI 50 ns 60 ns AS4C4M4F1 ordering information Package \ RAS access time Plastic SOJ, 300 mil, 24/26-pin 5V AS4C4M4F1-50JC AS4C4M4F1-50JI AS4C4M4F1-60JC AS4C4M4F1-60JI Plastic TSOP, 300 mil, 24/26-pin 5V AS4C4M4F1-50TC AS4C4M4F1-50TI AS4C4M4F1-60TC AS4C4M4F1-60TI AS4C4M4F0/F1 family part numbering system AS4 C 4M4 F0/F1 –XX X DRAM prefix C = 5V CMOS 4M×4 F0=4K refresh F1=2K refresh RAS access time Package: Temperature range J = SOJ 300 mil, 24/26 C=Commercial, 0°C to 70 °C T = TSOP 300 mil, 24/26 I=Industrial, -40°C to 85°C 4/11/01; v.0.9 Alliance Semiconductor X P. 17 of 18 © Copyright Alliance Semiconductor Corporation. All rights reserved. Our three-point logo, our name and Intelliwatt are trademarks or registered trademarks of Alliance. All other brand and product names may be the trademarks of their respective companies. Alliance reserves the right to make changes to this document and its products at any time without notice. Alliance assumes no responsibility for any errors that may appear in this document. The data contained herein represents Alliance's best data and/or estimates at the time of issuance. Alliance reserves the right to change or correct this data at any time, without notice. If the product described herein is under development, significant changes to these specifications are possible. The information in this product data sheet is intended to be general descriptive information for potential customers and users, and is not intended to operate as, or provide, any guarantee or warrantee to any user or customer. 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Alliance does not authorize its products for use as critical components in life-supporting systems where a malfunction or failure may reasonably be expected to result in significant injury to the user, and the inclusion of Alliance products in such life-supporting systems implies that the manufacturer assumes all risk of such use and agrees to indemnify Alliance against all claims arising from such use. AS4C4M4F0 AS4C4M4F1 ® 4/11/01; v.0.9 Alliance Semiconductor P. 18 of 18