64K x 32 3.3V Synchronous SRAM Flow-Through Outputs Burst Counter, Single Cycle Deselect IDT71V633 Features ◆ ◆ ◆ ◆ ◆ ◆ ◆ ◆ 64K x 32 memory configuration Supports high performance system speed Commercial: — 11 11ns Clock-to-Data Access (50 MHz) Commercial and Industrial: — 12 12ns Clock-to-Data Access (50 MHz) Single-cycle deselect functionality (Compatible with Micron Part # MT58LC64K32B2LG-XX) LBO input selects interleaved or linear burst mode Self-timed write cycle with global write control (GW), byte write enable (BWE), and byte writes (BWx) Power down controlled by ZZ input Single 3.3V power supply (+10/-5%) Packaged in a JEDEC Standard 100-pin rectangular plastic thin quad flatpack (TQFP). tecture provides cost-effective 2-1-1-1 performance for processors up to 50 MHz. The IDT71V633 SRAM contains write, data-input, address and control registers. There are no registers in the data output path (flow-through architecture). Internal logic allows the SRAM to generate a self-timed write based upon a decision which can be left until the extreme end of the write cycle. The burst mode feature offers the highest level of performance to the system designer, as the IDT71V633 can provide four cycles of data for a single address presented to the SRAM. An internal burst address counter accepts the first cycle address from the processor, initiating the access sequence. The first cycle of output data will flow-through from the array after a clock-to-data access time delay from the rising clock edge of the same cycle. If burst mode operation is selected (ADV=LOW), the subsequent three cycles of output data will be available to the user on the next three rising clock edges. The order of these three addresses will be defined by the internal burst counter and the LBO input pin. The IDT71V633 SRAM utilizes IDT's high-performance 3.3V CMOS process, and is packaged in a JEDEC Standard 14mm x 20mm 100-pin thin plastic quad flatpack (TQFP). Description The IDT71V633 is a 3.3V high-speed 2,097,152-bit (2-Mbit) SRAM organized as 64K x 32 with full support of various processor interfaces including the Pentium™ and PowerPC™. The flow-through burst archi- Pin Description A0–A15 Address Inputs Input Synchronous CE Chip Enable Input Synchronous CS0, CS1 Chips Selects Input Synchronous OE Output Enable Input Asynchronous GW Global Write Enable Input Synchronous BWE Byte Write Enable Input Synchronous BW1–BW4 Individual Byte Write Selects Input Synchronous CLK Clock Input Input N/A ADV Burst Address Advance Input Synchronous ADSC Address Status (Cache Controller) Input Synchronous ADSP Address Status (Processor) Input Synchronous LBO Linear / Interleaved Burst Order Input DC ZZ Sleep Mode Input Asynchronous I/O0–I/O31 Data Input/Output I/O Synchronous VDD, VDDQ Core and I/O Power Supply (3.3V) Power N/A VSS, VSSQ Array Ground, I/O Ground Power N/A 3780 tbl 01 Pentium is a trademark of Intel Corp. PowerPC is a trademark of International Business Machines, Inc. AUGUST 2001 1 ©2000 Integrated Device Technology, Inc. DSC-3780/05 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Pin Definitions(1) Symbol Pin Function I/O Active A0–A15 Address Inputs I N/A Synchronous Address inputs. The address register is triggered by a combination of the rising edge of CLK and ADSC Low or ADSP Low and CE Low. ADSC Address Status (Cache Controller) I LOW Synchronous Address Status from Cache Controller. ADSC is an active LOW input that is used to load the address registers with new addresses. ADSC is NOT gated by CE. ADSP Address Status (Processor) I LOW Synchronous Address Status from Processor. ADSP is an active LOW input that is used to load the address registers with new addresses. ADSP is gated by CE. ADV Burst Address Advance I LOW Synchronous Address Advance. ADV is an active LOW input that is used to advance the internal burst counter, controlling burst access after the initial address is loaded. When this input is HIGH the burst counter is not incremented; that is, there is no address advance. BWE Byte Write Enable I LOW Synchronous byte write enable gates the byte write inputs BW1–BW4. If BWE is LOW at the rising edge of CLK then BWX inputs are passed to the next stage in the circuit. A byte write can still be blocked if ADSP is LOW at the rising edge of CLK. If ADSP is HIGH and BWX is LOW at the rising edge of CLK then data will be written to the SRAM. If BWE is HIGH then the byte write inputs are blocked and only GW can initiate a write cycle. Individual Byte Write Enables I LOW Synchronous byte write enables. BW1 controls I/O(7:0), BW2 controls I/O(15:8), etc. Any active byte write causes all outputs to be disabled. ADSP LOW disables all byte writes. BW1–BW4 must meet specified setup and hold tim es with respect to CLK. CE Chip Enable I LOW Synchronous chip enable. CE is used with CS0 and CS1 to enable the IDT71V633. CE also gates ADSP. CLK Clock I N/A This is the clock input. All timing references for the device are made with respect to this input. CS0 Chip Select 0 I HIGH Synchronous active HIGH chip select. CS0 is used with CE and CS1 to enable the chip. CS1 Chip Select 1 I LOW Synchronous active LOW chip select. CS1 is used with CE and CS0 to enable the chip. GW Global Write Enable I LOW Synchronous global write enable. This input will write all four 8-bit data bytes when LOW on the rising edge of CLK. GW supercedes individual byte write enables. I/O0–I/O31 Data Input/Output I/O N/A Synchronous data input/output (I/O) pins. Only the data input path is registered and triggered by the rising edge of CLK. Outputs are Flow-Through. LBO Linear Burst I LOW When LBO is HIGH the Interleaved Order (Intel) burst sequence is selected. When LBO is LOW the Linear (PowerPC) burst sequence is selected. LBO has an internal pull-up resistor. OE Output Enable I LOW Asynchronous output enable. When OE is HIGH the I/O pins are in a high-impedence state. When OE is LOW the data output drivers are enabled if the chip is also selected. VDD Power Supply N/A N/A 3.3V core power supply inputs. VDDQ Power Supply N/A N/A 3.3V I/O power supply inputs. VSS Ground N/A N/A Core ground pins. VSSQ Ground N/A N/A I/O ground pins. NC No Connect N/A N/A NC pins are not electrically connected to the chip. ZZ Sleep Mode I HIGH BW1–BW4 Description Asynchronous sleep mode input. ZZ HIGH will gate the CLK internally and power down the IDT71V633 to its lowest pow er consumption level. Data retention is guaranteed in Sleep Mode. ZZ has an internal pull-down resistor. NOTE: 1. All synchronous inputs must meet specified setup and hold times with respect to CLK. 2 3780 tbl 02 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Functional Block Diagram LBO ADV CLK 2 Binary Counter ADSC INTERNAL ADDRESS Burst Sequence CE Burst Logic Q0 CLR ADSP Q1 CLK EN ADDRESS REGISTER A0–A15 GW BWE 2 A0, A1 64K x 32 BIT MEMORY ARRAY 16 A0* A1* A2–A15 32 32 16 Byte 1 Write Register Byte 1 Write Driver BW1 8 Byte 2 Write Register Byte 2 Write Driver BW2 8 Byte 3 Write Register Byte 3 Write Driver BW3 8 Byte 4 Write Register Byte 4 Write Driver BW4 8 CE D CS0 CS1 Q Enable Register DATA INPUT REGISTER CLK EN ZZ Powerdown OE OE OUTPUT BUFFER 32 I/O0–I/O31 3780 drw 01 3 6.42 . IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Absolute Maximum DC Ratings(1) Symbol Value Unit Terminal Voltage with Respect to GND –0.5 to +4.6 V Terminal Voltage with Respect to GND –0.5 to VDD+0.5 TA Operating Temperature 0 to +70 o TBIAS Temperature Under Bias –55 to +125 o –55 to +125 o VTERM (2) VTERM (3) Rating Recommended Operating Temperature and Supply Voltage V Grade Temperature VSS VDD VDDQ Commercial 0°C to +70°C 0V 3.3V+10/-5% 3.3V+10/-5% Industrial –40°C to +85°C 0V 3.3V+10/-5% 3.3V+10/-5% 3780 tbl 03 TSTG Storage Temperature C C Recommended DC Operating Conditions C PT Power Dissipation 1.2 W IOUT DC Output Current 50 mA Symbol 3780 tbl 05 VDD VDDQ NOTES: 1. 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 operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. 2. VDD, VDDQ and input terminals only. 3. I/O terminals. VIH VIL CIN Input Capacitance CI/O I/O Capacitance Conditions Max. Unit VIN = 3dV 4 pF VOUT = 3dV 8 Typ. Max. Unit Core Supply Voltage 3.135 3.3 3.63 V I/O Supply Voltage 3.135 3.3 3.63 V 0 0 Input High Voltage Input Low Voltage 0 2.0 (1) –0.5 (3) ____ ____ VDDQ+0.3 V (2) 0.8 V V 3780 tbl 04 NOTES: 1. VIH and VIL as indicated is for both input and I/O pins. 2. VIH (max) = 6.0V for pulse width less than tCYC/2, once per cycle. 3. VIL (min) = –1.0V for pulse width less than tCYC/2, once per cycle. (TA = +25°C, f = 1.0MHz, TQFP package) Parameter(1) Min. VSS, VSSQ Ground Capacitance Symbol Parameter pF 3780 tbl 06 NOTE: 1. This parameter is guaranteed by device characterization, but not production tested. 4 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges A6 A7 CE CS0 BW4 BW3 BW2 BW1 CS1 VDD VSS CLK GW BWE OE ADSC ADSP ADV A8 A9 Pin Configuration 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 NC I/O16 I/O17 VDDQ VSSQ I/O18 I/O19 I/O20 I/O21 VSSQ VDDQ I/O22 I/O23 VSS(1) VDD NC VSS I/O24 I/O25 VDDQ VSSQ I/O26 I/O27 I/O28 I/O29 VSSQ VDDQ I/O30 I/O31 NC 1 80 2 79 3 78 4 77 5 76 6 75 7 74 8 73 9 72 71 10 11 70 12 69 13 68 14 67 15 PK100-1 66 16 65 17 64 18 63 19 62 20 61 21 60 22 59 23 58 24 57 25 56 26 55 27 54 28 53 29 52 30 51 NC I/O15 I/O14 VDDQ VSSQ I/O13 I/O12 I/O11 I/O10 VSSQ VDDQ I/O9 I/O8 VSS NC VDD ZZ(2) I/O7 I/O6 VDDQ VSSQ I/O5 I/O4 I/O3 I/O2 VSSQ VDDQ I/O1 I/O0 NC LBO A5 A4 A3 A2 A1 A0 NC NC VSS VDD NC NC A10 A11 A12 A13 A14 A15 NC 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 Top View TQFP NOTES 1. Pin 14 does not have to be directly connected to VSS as long as the input voltage is ≤ VIL. 2. Pin 64 can be left unconnected and the device will always remain in active mode. 5 6.42 3780 drw 02 . IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Synchronous Truth Table(1, 2) Address Used CE CS0 CS 1 ADSP ADSC ADV GW BWE BWX OE (3) CLK I/O Deselected Cycle, Power Down None H X X X L X X X X X ↑ Hi-Z Deselected Cycle, Power Down None L X H L X X X X X X ↑ Hi-Z Deselected Cycle, Power Down None L L X L X X X X X X ↑ Hi-Z Deselected Cycle, Power Down None L X H X L X X X X X ↑ Hi-Z Deselected Cycle, Power Down None L L X X L X X X X X ↑ Hi-Z Read Cycle, Begin Burst External L H L L X X X X X L ↑ DOUT Read Cycle, Begin Burst External L H L L X X X X X H ↑ Hi-Z Read Cycle, Begin Burst External L H L H L X H H X L ↑ DOUT Read Cycle, Begin Burst External L H L H L X H L H L ↑ DOUT Read Cycle, Begin Burst External L H L H L X H L H H ↑ Hi-Z Write Cycle, Begin Burst External L H L H L X H L L X ↑ DIN Write Cycle, Begin Burst External L H L H L X L X X X ↑ DIN Read Cycle, Continue Burst Next X X X H H L H H X L ↑ DOUT Read Cycle, Continue Burst Next X X X H H L H H X H ↑ Hi-Z Read Cycle, Continue Burst Next X X X H H L H X H L ↑ DOUT Read Cycle, Continue Burst Next X X X H H L H X H H ↑ Hi-Z Read Cycle, Continue Burst Next H X X X H L H H X L ↑ DOUT Read Cycle, Continue Burst Next H X X X H L H H X H ↑ Hi-Z Read Cycle, Continue Burst Next H X X X H L H X H L ↑ DOUT Read Cycle, Continue Burst Next H X X X H L H X H H ↑ Hi-Z Write Cycle, Continue Burst Next X X X H H L H L L X ↑ DIN Write Cycle, Continue Burst Next X X X H H L L X X X ↑ DIN Write Cycle, Continue Burst Next H X X X H L H L L X ↑ DIN Write Cycle, Continue Burst Next H X X X H L L X X X ↑ DIN Read Cycle, Suspend Burst Current X X X H H H H H X L ↑ DOUT Read Cycle, Suspend Burst Current X X X H H H H H X H ↑ Hi-Z Read Cycle, Suspend Burst Current X X X H H H H X H L ↑ DOUT Read Cycle, Suspend Burst Current X X X H H H H X H H ↑ Hi-Z Read Cycle, Suspend Burst Current H X X X H H H H X L ↑ DOUT Read Cycle, Suspend Burst Current H X X X H H H H X H ↑ Hi-Z Read Cycle, Suspend Burst Current H X X X H H H X H L ↑ DOUT Read Cycle, Suspend Burst Current H X X X H H H X H H ↑ Hi-Z Write Cycle, Suspend Burst Current X X X H H H H L L X ↑ DIN Write Cycle, Suspend Burst Current X X X H H H L X X X ↑ DIN Write Cycle, Suspend Burst Current H X X X H H H L L X ↑ DIN Write Cycle, Suspend Burst Current H X X X H H L X X X ↑ Operation DIN 3780 tbl 07 NOTES: 1. L = VIL, H = VIH, X = Don’t Care. 2. ZZ = LOW for this table. 3. OE is an asynchronous input. 6 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Synchronous Write Function Truth Table(1) GW BWE BW1 BW2 BW3 BW4 Read H H X X X X Read H L H H H H Write all Bytes L X X X X X Write all Bytes H L L L L L Write Byte 1 (2) H L L H H H Write Byte 2 (2) H L H L H H Write Byte 3 (2) H L H H L H Write Byte 4 (2) H L H H H L Operation 3780 tbl 08 NOTES: 1. L = VIL, H = VIH, X = Don’t Care. 2. Multiple bytes may be selected during the same cycle. Asynchronous Truth Table(1) OE ZZ I/O Status Power Read L L Data Out (I/O0–I/O31) Active Read H L High-Z Active Write X L High-Z — Data In (I/O 0–I/O31) Active Deselected X L High-Z Standby Sleep Mode X H High-Z Sleep Operation 3780 tbl 09 NOTES: 1. L = VIL, H = VIH, X = Don’t Care. 2. Synchronous function pins must be biased appropriately to satisfy operation requirements. Interleaved Burst Sequence Table (LBO=VDD) Sequence 1 Sequence 2 Sequence 3 Sequence 4 A1 A0 A1 A0 A1 A0 A1 A0 First Address 0 0 0 1 1 0 1 1 Second Address 0 1 0 0 1 1 1 0 Third Address 1 0 1 1 0 0 0 1 Fourth Address(1) 1 1 1 0 0 1 0 0 3780 tbl 10 NOTE: 1. Upon completion of the Burst sequence the counter wraps around to its initial state. Linear Burst Sequence Table (LBO=VSS) Sequence 1 Sequence 2 Sequence 3 Sequence 4 A1 A0 A1 A0 A1 A0 A1 A0 First Address 0 0 0 1 1 0 1 1 Second Address 0 1 1 0 1 1 0 0 Third Address 1 0 1 1 0 0 0 1 1 1 0 0 0 1 1 0 (1) Fourth Address NOTE: 1. Upon completion of the Burst sequence the counter wraps around to its initial state. 7 6.42 3780 tbl 11 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges DC Electrical Characteristics Over the Operating Temperature and Supply Voltage Range (VDD = 3.3V +10/-5%) Symbol Min. Max. Unit VDD = Max., VIN = 0V to VDD ___ 5 µA VDD = Max., VIN = 0V to VDD ___ 30 µA 5 µA Parameter Test Conditions |ILI| Input Leakage Current |ILI| ZZ & LBO Input Leakage Current (1) |ILO| Output Leakage Current CE > VIH or OE > VIH, VOUT = 0V to VDD, VDD = Max. ___ VOL Output Low Voltage IOL = 5mA, VDD = Min. ___ 0.4 V VOH Output High Voltage IOH = –5mA, VDD = Min. 2.4 ___ V 3780 tbl 12 NOTE: 1. The LBO pin will be internally pulled to VDD if it is not actively driven in the application and the ZZ pin will be internally pulled to V SS if not actively driven. DC Electrical Characteristics Over the Operating Temperature and Supply Voltage Range(1) (VHD = VDDQ0.2V, VLD = 0.2V) IDT71V633S11(3) Symbol Parameter Test Conditions IDT71V633S12 Com'l Ind'l Com'l Ind'l Unit IDD Operating Core Power Supply Current Device Selected, Outputs Open, VDD = Max., VDDQ = Max., VIN > VIH or < VIL, f = fMAX(2) 160 — 150 150 mA ISB Standby Core Power Supply Current Device Deselected, Outputs Open, VDD = Max., VDDQ = Max., VIN > VIH or < VIL, f = fMAX(2) 45 — 40 40 mA ISB1 Full Standby Core Power Supply Current Device Deselected, Outputs Open, VDD = Max., VDDQ = Max., VIN > VHD or < VLD, f = 0(2) 15 — 15 15 mA IZZ Full Sleep Mode Core Power Supply Current ZZ > VHD, VDD = Max. 15 — 15 15 mA NOTES: 1. All values are maximum guaranteed values. 2. At f = fMAX, inputs are cycling at the maximum frequency of read cycles of 1/tCYC while ADSC = LOW; f=0 means no input lines are changing. 3. 0°C to +70°C temperature range only. +3.3V AC Test Loads VDDQ/2 317Ω 50Ω DATA OUT 3780 tbl 13 DATA OUT 351Ω Z0 = 50Ω 5pF* 3780 drw 03 Figure 1. AC Test Load 3780 drw 04 * Including scope and jig capacitance. 6 Figure 2. High-Impedence Test Load (for tOHZ, tCHZ, tOLZ, and tDC1) 5 4 AC Test Conditions 3 ∆tCD (Typical, ns) 2 Input Pulse Levels 1 20 30 50 80 100 Capacitance (pF) 200 2ns Input Timing Reference Levels 1.5V Output Timing Reference Levels AC Test Load 3780 drw 05 Figure 3. Lumped Capacitive Load, Typical Derating 0 to 3.0V Input Rise/Fall Times 1.5V See Figures 1 and 2 3780 tbl 14 8 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges AC Electrical Characteristics (VDD = 3.3V +10/-5%, Commercial and Industrial Temperature Ranges) 71V633S11(5) Symbol Parameter 71V633S12 Min. Max. Min. Max. Unit 20 ____ 20 ____ ns 6 ____ ns ____ ns Clock Parameters tCYC Clock Cycle Time (1) Clock High Pulse Width 6 ____ (1) Clock Low Pulse Width 6 ____ 6 ____ 11 ____ 12 ns 3 ____ 3 ____ ns 0 ____ ns tCH tCL Output Parameters tCD Clock High to Valid Data tCDC tCLZ Clock High to Data Change (2) Clock High to Output Active 0 ____ (2) Clock High to Data High-Z 3 6 3 6 ns ____ 4 ____ 4 ns tCHZ tOE Output Enable Access Time tOLZ(2) Output Enable Low to Data Active 0 ____ 0 ____ ns tOHZ (2) Output Enable High to Data High-Z ____ 6 ____ 6 ns Address Setup Time 2.5 ____ 2.5 ____ ns 2.5 ____ ns Setup Times tSA tSS Address Status Setup Time 2.5 ____ tSD Data in Setup Time 2.5 ____ 2.5 ____ ns tSW Write Setup Time 2.5 ____ 2.5 ____ ns 2.5 ____ 2.5 ____ ns Chip Enable/Select Setup Time 2.5 ____ 2.5 ____ ns tHA Address Hold Time 0.5 ____ 0.5 ____ ns tHS Address Status Hold Time 0.5 ____ 0.5 ____ ns tHD Data In Hold Time 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns tSAV Address Advance Setup Time tSC Hold Times tHW Write Hold Time tHAV Address Advance Hold Time tHC Chip Enable/Select Hold Time Sleep Mode and Configuration Parameters tZZPW ZZ Pulse Width 100 ____ 100 ____ ns tZZR(3) ZZ Recovery Time 100 ____ 100 ____ ns 80 ____ 80 ____ tCFG (4) Configuration Set-up Time NOTES: 1. Measured as HIGH above 2.0V and LOW below 0.8V. 2. Transition is measured ±200mV from steady-state. 3. Device must be deselected when powered-up from sleep mode. 4. tCFG is the minimum time required to configure the device based on the LBO input. LBO is a static input and must not change during normal operation. 5. 0°C to +70°C temperature range only. 9 6.42 ns 3780 tbl 15 10 Output Disabled tSC tSA tSS tHS tOLZ tOE O1(Ax) tHC Flow-through Read Ax tHA tOHZ Ay (1) tCH O1(Ay) tCDC tCD tSW tCL tSAVtHAV O3(Ay) O4(Ay) (Burst wraps around to its initial state) ADV inserts a wait-state Burst Flow-through Read O2(Ay) tHW O1(Ay) tCHZ O2(Ay) 3780 drw 06 Timing Waveform of Read Cycle(1,2) . NOTES: 1. O1 (Ax) represents the first output from the external address Ax. O1 (Ay) represents the first output from the external address Ay; O2 (Ay) represents the next output data in the burst sequence of the base address Ay, etc., where A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. 2. ZZ input is LOW and LBO is Don’t Care for this cycle. 3. CS0 timing transitions are identical but inverted to the CE and CS1 signals. For example, when CE and CS1 are LOW on this waveform, CS0 is HIGH. DATAOUT OE ADV (Note 3) CE, CS1 GW, BWE, BWx ADDRESS ADSC ADSP CLK tCYC IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges 11 6.42 Ax (2) Single Read tSA tHA tSS tHS tCLZ tCD tOE O1(Ax) tOHZ tSW Ay tCH Write I1(Ay) tSD tHD tCL tHW Az tCDC tOLZ O2(Az) O3(Az) Flow-through Burst Read O1(Az) 3780 drw 07 O4(Az) . NOTES: 1. Device is selected through entire cycle; CE and CS1 are LOW, CS0 is HIGH. 2. ZZ input is LOW and LBO is Don't Care for this cycle. 3. O1 (Ax) represents the first output from the external address Ax. I1 (Ay) represents the first input from the external address Ay. O1 (Az) represents the first output from the external address Az; O2 (Az) represents the next output data in the burst sequence of the base address Az, etc., where A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. DATAOUT DATAIN OE ADV GW ADDRESS ADSP CLK tCYC IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Combined Read and Write Cycles(1,2,3) 12 O3(Aw) tSC tHC tSA tHA tSS tHS Ax O4(Aw) (1) . Ay tCL tOHZ I1(Ax) I1(Ay) BWE is ignored when ADSP initiates burst tCH I2(Ay) (ADV suspends burst) tSAV I2(Ay) (3) I3(Ay) tHAV I4(Ay) tSD I1(Az) tHW tSW Az I3(Az) 3780 drw 08 I2(Az) tHD NOTES: 1. ZZ input is LOW, BWE is HIGH, and LBO is Don’t Care for this cycle. 2. O4 (Aw) represents the final output data in the burst sequence of the base address Aw. I1 (Ax) represents the first input from the external address Ax. I1 (Ay) represents the first input from the external address Ay; I2 (Ay) represents the next input data in the burst sequence of the base address Ay, etc., where A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. In the case of input I2(Ay) this data is valid for two cycles because ADV is high and has suspended the burst. 3. CS0 timing transitions are identical but inverted to the CE and CS1 signals. For example, when CE and CS1 are LOW on this waveform, CS0 is HIGH. DATAOUT DATAIN OE ADV (Note 3) CE, CS1 GW ADDRESS ADSC ADSP CLK tCYC IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Write Cycle No. 1 GW Controlled(1,2,3) 13 6.42 Burst Read O3(Aw) tSC tHC tSA tHA tSS tHS O4(Aw) Ax . (ADV suspends burst) I2(Ay) I3(Ay) tSD Single Write tOHZ I1(Ax) I1(Ay) Burst Write I2(Ay) I4(Ay) Extended Burst Write I1(Az) tSAV tHW tSW BWx is ignored when ADSP initiates burst Az tHW tSW Ay tCL BWE is ignored when ADSP initiates burst tCH I2(Az) tHD 3780 drw 09 I3(Az) NOTES: 1. ZZ input is LOW, GW is HIGH, and LBO is Don’t Care for this cycle. 2. O4 (Aw) represents the final output data in the burst sequence of the base address Aw. I1 (Ax) represents the first input from the external address Ax. I1 (Ay) represents the first input from the external address Ay; I2 (Ay) represents the next input data in the burst sequence of the base address Ay, etc., where A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. In the case of input I2(Ay) this data is valid for two cycles because ADV is high and has suspended the burst. 3. CS0 timing transitions are identical but inverted to the CE and CS1 signals. For example, when CE and CS1 are LOW on this waveform, CS0 is HIGH. DATAOUT DATAIN OE ADV (Note 3) CE, CS1 BWx BWE ADDRESS ADSC ADSP CLK tCYC IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Write Cycle No. 2 Byte Controlled(1,2,3) 14 tSS tSC tSA tHS tOLZ Ax O1(Ax) Single Read tOE tHC tHA tCH tCL tZZPW Snooze Mode . t ZZR NOTES: 1. Device must power up in deselected mode. 2. LBO input is Don’t Care for this cycle. 3. It is not necessary to retain the state of the input registers throughout the Power-down cycle. 4. CS0 timing transitions are identical but inverted to the CE and CS1 signals. For example, when CE and CS1 are LOW on this waveform, CS0 is HIGH. ZZ DATAOUT OE ADV (Note 4) CE, CS1 GW ADDRESS ADSC ADSP CLK tCYC Az 3780 drw 10 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Sleep (ZZ) and Power-Down Modes(1,2,3) IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Non-Burst Read Cycle Timing Waveform CLK ADSP ADSC ADDRESS Av Aw Ax Ay Az GW, BWE, BWx CE, CS1 CS0 OE DATAOUT (Av) (Aw) (Ax) (Ay) . 3780 drw 11 NOTES: 1 ZZ input is LOW, ADV is HIGH, and LBO is Don’t Care for this cycle. 2. (Ax) represents the data for address Ax, etc. 3. For read cycles, ADSP and ADSC function identically and are therefore interchangeable. 15 6.42 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Non-Burst Write Cycle Timing Waveform CLK ADSP ADSC ADDRESS Av Aw Ax Ay Az (Ax) (Ay) (Az) GW CE, CS1 CS0 DATAIN (Av) (Aw) 3780 drw 12 NOTES: 1. ZZ input is LOW, ADV and OE are HIGH, and LBO is Don't Care for this cycle. 2. (Ax) represents the data for address Ax, etc. 3. Although only GW writes are shown, the functionality of BWE and BWx together is the same as GW. 4. For write cycles, ADSP and ADSC have different limitations. 16 . IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges 100-pin Thin Quad Plastic Flatpack (TQFP) Package Diagram Outline 17 6.42 IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Ordering Information IDT 71V633 S X PF X Device Type Power Speed Package Process/ Temperature Range Blank I Commercial (0°C to +70°C) Industrial (–40°C to +85°C) PF Plastic Thin Quad Flatpack, 100 pin (PK100-1) 11* 12 tCD in nanoseconds * Commercial only. PART NUMBER SPEED IN MEGAHERTZ tCD PARAMETER CLOCK CYCLE TIME 71V633S11PF 50 MHz 11 ns 20 ns 71V633S12PF 50 MHz 12 ns 20 ns 3780 drw 13 18 . IDT71V633, 64K x 32, 3.3V Synchronous SRAM with Flow-Through Outputs Commercial and Industrial Temperature Ranges Datasheet Document History 9/9/99 9/30/99 10/8/99 04/04/00 08/09/00 08/17/01 Pg. 6–8 Pg. 10–14 Pg. 18 Pg. 1, 4, 8, 9, 17 Pg. 1 Pg. 17 Updated to new format Reordered pages, updated notes Updated notes Added Datasheet Document History Added Industrial temperature range offering Corrected –12 speed Added 100pinTQFP Package Diagram Outline Not recommended for new designs Removed “Not recommended for new designs” from the background on the datasheet CORPORATE HEADQUARTERS 2975 Stender Way Santa Clara, CA 95054 for SALES: 800-345-7015 or 408-727-6116 fax: 408 492-8674 www.idt.com The IDT logo is a registered trademark of Integrated Device Technology, Inc. 19 6.42 for TECH SUPPORT: [email protected] 800 544-7726, x4033