PRELIMINARY CMOS SRAM K6R4008V1D Document Title 512Kx8 Bit High Speed Static RAM(3.3V Operating). Operated at Commercial and Industrial Temperature Ranges. Revision History Rev No. History Draft Data Rev. 0.0 Initial release with Preliminary. Aug. 20. 2001 Preliminary Rev. 0.1 Add Low Ver. Sep. 19. 2001 Preliminary Rev. 0.2 Change Icc, Isb and Isb1 Nov. 3. 2001 Preliminary Nov.23. 2001 Preliminary Dec.18. 2001 Final July. 26, 2004 Final Item ICC(Commercial) ICC(Industrial) 8ns 10ns 12ns 15ns 8ns 10ns 12ns 15ns ISB ISB1(L-ver.) Rev. 0.3 Rev. 1.0 Rev. 2.0 Previous 110mA 90mA 80mA 70mA 130mA 115mA 100mA 85mA 30mA 0.5mA Current 80mA 65mA 55mA 45mA 100mA 85mA 75mA 65mA 20mA 1.2mA 1. Correct AC parameters : Read & Write Cycle mA 2. Delete Low Ver. 3. Delete Data Retention Characteristics 1. Delete 12ns,15ns speed bin. 2. Change Icc for Industrial mode. Item 8ns ICC(Industrial) 10ns Previous 100mA 85mA 1. Add the Lead Free Package type. Remark Current 90mA 75mA The attached data sheets are prepared and approved by SAMSUNG Electronics. SAMSUNG Electronics CO., LTD. reserve the right to change the specifications. SAMSUNG Electronics will evaluate and reply to your requests and questions on the parameters of this device. If you have any questions, please contact the SAMSUNG branch office near your office, call or contact Headquarters. -1- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D 4Mb Async. Fast SRAM Ordering Information Org. Part Number VDD(V) Speed ( ns ) 5 10 K6R4004V1D-J(K)C(I) 08/10 3.3 8/10 K6R4008C1D-J(K,T,U)C(I) 10 5 10 K6R4008V1D-J(K,T,U)C(I) 08/10 3.3 8/10 K6R4016C1D-J(K,T,U,E)C(I) 10 5 10 3.3 8/10 K6R4004C1D-J(K)C(I) 10 1M x4 512K x8 256K x16 K6R4016V1D-J(K,T,U,E)C(I,L,P) 08/10 -2- PKG Temp. & Power J : 32-SOJ K : 32-SOJ(LF) C : Commercial Temperature ,Normal Power Range I : Industrial Temperature J : 36-SOJ K : 36-SOJ(LF) ,Normal Power Range T : 44-TSOP2 L : Commercial Temperature U : 44-TSOP2(LF) ,Low Power Range P : Industrial Temperature J : 44-SOJ ,Low Power Range K : 44-SOJ(LF) T : 44-TSOP2 U : 44-TSOP2(LF) E : 48-TBGA Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D 512K x 8 Bit High-Speed CMOS Static RAM FEATURES GENERAL DESCRIPTION • Fast Access Time 8,10ns(Max.) • Low Power Dissipation Standby (TTL) : 20mA(Max.) (CMOS) : 5mA(Max.) Operating K6R4008V1D-08 : 80mA(Max.) K6R4008V1D-10 : 65mA(Max.) • Single 3.3 ±0.3V Power Supply • TTL Compatible Inputs and Outputs • Fully Static Operation - No Clock or Refresh required • Three State Outputs • Center Power/Ground Pin Configuration • Standard Pin Configuration K6R4008V1D-J : 36-SOJ-400 K6R4008V1D-K : 36-SOJ-400(Lead-Free) K6R4008V1D-T : 44-TSOP2-400BF K6R4008V1D-U : 44-TSOP2-400BF(Lead-Free) • Operating in Commercial and Industrial Temperature range. The K6R4008V1D is a 4,194,304-bit high-speed Static Random Access Memory organized as 524,288 words by 8 bits. The K6R4008V1D uses 8 common input and output lines and has an output enable pin which operates faster than address access time at read cycle. The device is fabricated using SAMSUNG′s advanced CMOS process and designed for high-speed circuit technology. It is particularly well suited for use in high-density high-speed system applications. The K6R4008V1D is packaged in a 400 mil 36-pin plastic SOJ and 44-pin plastic TSOP type II. FUNCTIONAL BLOCK DIAGRAM A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 I/O1~I/O8 Pre-Charge Circuit Row Select Clk Gen. Memory Array 1024 Rows 512 x 8 Columns Data Cont. I/O Circuit Column Select CLK Gen. A10 A11 A12 A13 A14 A15 A16 A17 A18 CS WE OE -3- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D PIN CONFIGURATION (Top View) 1 A0 36 N.C N.C 1 44 N.C N.C 2 43 N.C A0 3 42 N.C A1 4 A1 2 35 A18 A2 3 34 A17 41 A18 A3 4 33 A16 A2 5 40 A17 A4 5 32 A15 A3 6 39 A16 CS 6 31 OE A4 7 38 A15 I/O1 7 30 I/O8 CS 8 37 OE I/O2 8 I/O1 9 36 I/O8 Vcc 9 Vss 10 27 Vcc Vss 12 33 Vcc I/O3 11 26 I/O6 I/O3 13 32 I/O6 25 I/O5 I/O4 14 31 I/O5 WE 15 30 A14 A5 16 29 A13 A6 17 28 A12 29 I/O7 36-SOJ I/O2 10 28 Vss I/O4 12 Vcc 11 35 I/O7 44-TSOP2 34 Vss WE 13 24 A14 A5 14 23 A13 A6 15 22 A12 A7 18 27 A11 A7 16 21 A11 A8 19 26 A10 A8 17 20 A10 A9 A9 18 19 N.C 20 25 N.C N.C 21 24 N.C N.C 22 23 N.C PIN FUNCTION Pin Name A0 - A18 Pin Function Address Inputs WE Write Enable CS Chip Select OE Output Enable I/O1 ~ I/O8 VCC Data Inputs/Outputs Power(+3.3V) VSS Ground N.C No Connection ABSOLUTE MAXIMUM RATINGS* Parameter Symbol Rating Unit VIN, VOUT -0.5 to 4.6 V Voltage on VCC Supply Relative to VSS VCC -0.5 to 4.6 V Power Dissipation PD 1.0 W Voltage on Any Pin Relative to VSS TSTG -65 to 150 °C Commercial TA 0 to 70 °C Industrial TA -40 to 85 °C Storage Temperature Operating Temperature * Stresses greater than those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operating sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. -4- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D RECOMMENDED DC OPERATING CONDITIONS*(TA=0 to 70°C) Parameter Symbol Min Typ Max Unit Supply Voltage VCC 3.0 3.3 3.6 V Ground VSS 0 0 0 V Input High Voltage VIH 2.0 - VCC+0.3*** V Input Low Voltage VIL -0.3** - 0.8 V * The above parameters are also guaranteed at industrial temperature range. ** VIL(Min) = -2.0V a.c(Pulse Width ≤ 8ns) for I ≤ 20mA. *** VIH(Max) = VCC + 2.0V a.c (Pulse Width ≤ 8ns) for I ≤ 20mA DC AND OPERATING CHARACTERISTICS*(TA=0 to 70°C, Vcc=3.3±0.3V, unless otherwise specified) Min Max Unit Input Leakage Current ILI VIN=VSS to VCC -2 2 µA Output Leakage Current ILO CS=VIH or OE=VIH or WE=VIL VOUT=VSS to VCC -2 2 µA Operating Current ICC Min. Cycle, 100% Duty CS=VIL, VIN=VIH or VIL, IOUT=0mA 8ns - 80 mA 10ns - 65 Parameter Symbol Test Conditions Com. Ind. Standby Current 8ns - 90 10ns - 75 ISB Min. Cycle, CS=VIH - 20 ISB1 f=0MHz, CS≥VCC-0.2V, VIN≥VCC-0.2V or VIN≤0.2V - 5 Output Low Voltage Level VOL IOL=8mA - 0.4 V Output High Voltage Level VOH IOH=-4mA 2.4 - V mA * The above parameters are also guaranteed at industrial temperature range. CAPACITANCE*(TA=25°C, f=1.0MHz) Item Symbol Test Conditions TYP Max Unit Input/Output Capacitance CI/O VI/O=0V - 8 pF Input Capacitance CIN VIN=0V - 6 pF * Capacitance is sampled and not 100% tested. -5- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D AC CHARACTERISTICS(TA=0 to 70°C, VCC=3.3±0.3V, unless otherwise noted.) TEST CONDITIONS* Parameter Value Input Pulse Levels 0V to 3V Input Rise and Fall Times 3ns Input and Output timing Reference Levels 1.5V Output Loads See below *The above test conditions are also applied at industrial temperature range. Output Loads(A) Output Loads(B) for tHZ, tLZ, tWHZ, tOW, tOLZ & tOHZ +3.3V RL = 50Ω DOUT VL = 1.5V 319Ω DOUT 30pF* ZO = 50Ω 353Ω 5pF* * Including Scope and Jig Capacitance * Capacitive Load consists of all components of the test environment. READ CYCLE* Parameter Symbol K6R4008V1D-08 K6R4008V1D-10 Unit Min Max Min Max tRC 8 - 10 - ns Address Access Time tAA - 8 - 10 ns Chip Select to Output tCO - 8 - 10 ns Output Enable to Valid Output tOE - 4 - 5 ns Chip Enable to Low-Z Output tLZ 3 - 3 - ns Output Enable to Low-Z Output tOLZ 0 - 0 - ns Chip Disable to High-Z Output tHZ 0 4 0 5 ns Output Disable to High-Z Output tOHZ 0 4 0 5 ns Output Hold from Address Change tOH 3 - 3 - ns Chip Selection to Power Up Time tPU 0 - 0 - ns Chip Selection to Power DownTime tPD - 8 - 10 ns Read Cycle Time * The above parameters are also guaranteed at industrial temperature range. -6- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D WRITE CYCLE* Parameter K6R4008V1D-08 Symbol Min K6R4008V1D-10 Max Min Max Unit Write Cycle Time tWC 8 - 10 - ns Chip Select to End of Write tCW 6 - 7 - ns Address Set-up Time tAS 0 - 0 - ns Address Valid to End of Write tAW 6 - 7 - ns Write Pulse Width(OE High) tWP 6 - 7 - ns Write Pulse Width(OE Low) tWP1 8 - 10 - ns Write Recovery Time tWR 0 - 0 - ns Write to Output High-Z tWHZ 0 4 0 5 ns Data to Write Time Overlap tDW 4 - 5 - ns Data Hold from Write Time tDH 0 - 0 - ns End of Write to Output Low-Z tOW 3 - 3 - ns * The above parameters are also guaranteed at industrial temperature range. TIMING DIAGRAMS TIMING WAVEFORM OF READ CYCLE(1) (Address Controlled, CS=OE=VIL, WE=VIH) tRC Address tAA tOH Data Out Valid Data Previous Valid Data TIMING WAVEFORM OF READ CYCLE(2) (WE=VIH) tRC Address tAA tCO CS tHZ(3,4,5) tOHZ tOE OE tOLZ Data out High-Z VCC ICC Current ISB tDH tLZ(4,5) Valid Data tPU tPD 50% 50% NOTES(WRITE CYCLE) 1. WE is high for read cycle. 2. All read cycle timing is referenced from the last valid address to the first transition address. 3. tHZ and tOHZ are defined as the time at which the outputs achieve the open circuit condition and are not referenced to VOH or VOL levels. 4. At any given temperature and voltage condition, tHZ(Max.) is less than tLZ(Min.) both for a given device and from device to device. 5. Transition is measured ±200mV from steady state voltage with Load(B). This parameter is sampled and not 100% tested. 6. Device is continuously selected with CS=VIL. 7. Address valid prior to coincident with CS transition low. 8. For common I/O applications, minimization or elimination of bus contention conditions is necessary during read and write cycle. -7- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D TIMING WAVEFORM OF WRITE CYCLE(1) (OE= Clock) tWC Address tWR(5) tAW OE tCW(3) CS tWP(2) tAS(4) WE tDW Data in High-Z tDH Valid Data tOHZ(6) High-Z(8) Data out TIMING WAVEFORM OF WRITE CYCLE(2) (OE=Low Fixed) tWC Address tWR(5) tAW tCW(3) CS tAS(4) tWP1(2) WE tDW Data in High-Z tDH Valid Data tWHZ(6) tOW High-Z(8) Data out (10) (9) TIMING WAVEFORM OF WRITE CYCLE(3) (CS = Controlled) tWC Address tAW tWR(5) tCW(3) CS tAS(4) tWP(2) WE tDW Data in High-Z Valid Data tLZ Data out tDH High-Z tWHZ(6) High-Z(8) High-Z -8- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D NOTES(WRITE CYCLE) 1. All write cycle timing is referenced from the last valid address to the first transition address. 2. A write occurs during the overlap of a low CS and WE. A write begins at the latest transition CS going low and WE going low ; A write ends at the earliest transition CS going high or WE going high. tWP is measured from the beginning of write to the end of write. 3. tCW is measured from the later of CS going low to end of write. 4. tAS is measured from the address valid to the beginning of write. 5. tWR is measured from the end of write to the address change. tWR applied in case a write ends as CS or WE going high. 6. If OE, CS and WE are in the Read Mode during this period, the I/O pins are in the output low-Z state. Inputs of opposite phase of the output must not be applied because bus contention can occur. 7. For common I/O applications, minimization or elimination of bus contention conditions is necessary during read and write cycle. 8. If CS goes low simultaneously with WE going or after WE going low, the outputs remain high impedance state. 9. Dout is the read data of the new address. 10. When CS is low : I/O pins are in the output state. The input signals in the opposite phase leading to the output should not be applied. FUNCTIONAL DESCRIPTION CS WE OE Mode I/O Pin Supply Current H X L H X* Not Select High-Z ISB, ISB1 H Output Disable High-Z ICC L H L Read DOUT ICC L L X Write DIN ICC * X means Don′t Care. -9- Rev. 2.0 July 2004 PRELIMINARY CMOS SRAM K6R4008V1D PACKAGE DIMENSIONS Units:millimeters/Inches 36-SOJ-400 #36 #19 9.40 ±0.25 0.370 ±0.010 10.16 0.400 11.18 ±0.12 0.440 ±0.005 +0.10 -0.05 +0.004 0.008 -0.002 0.20 #1 #18 0.69 MIN 0.027 23.90 MAX 0.941 23.50 ±0.12 0.925 ±0.005 1.19 ) 0.047 1.27 ( ) 0.050 ( 0.43 ( 0.95 ) 0.0375 +0.10 -0.05 0.017 +0.004 -0.002 1.27 0.050 3.76 MAX 0.148 0.10 MAX 0.004 0.71 +0.10 -0.05 0.028 +0.004 -0.002 44-TSOP2-400BF Units:millimeters/Inches 0~8° 0.25 0.010 TYP #23 #44 11.76 ±0.20 0.463 ±0.008 10.16 0.400 0.45 ~0.75 0.018 ~ 0.030 ( 0.50 ) 0.020 #1 #22 18.81 MAX 0.741 0.075 0.125 +- 0.035 + 0.003 18.41 ±0.10 0.725 ±0.004 0.005 - 0.001 1.00 ±0.10 0.039 ±0.004 ( 0.805 ) 0.032 0.30 +0.10 −0.05 0.012 +0.004 −0.002 0.05 MIN 0.002 0.80 0.0315 - 10 1.20 MAX 0.047 0.10 0.004 MAX Rev. 2.0 July 2004