128K x 36, 256K x 18, 3.3V Synchronous ZBTTM SRAMs 3.3V I/O, Burst Counter, Flow-Through Outputs Features IDT71V3557S IDT71V3559S IDT71V3557SA IDT71V3559SA it read or write. The IDT71V3557/59 contain address, data-in and control signal registers. The outputs are flow-through (no output data register). Output enable is the only asynchronous signal and can be used to disable the outputs at any given time. A Clock Enable (CEN) pin allows operation of the IDT71V3557/59 to be suspended as long as necessary. All synchronous inputs are ignored when (CEN) is high and the internal device registers will hold their previous values. There are three chip enable pins (CE1, CE2, CE2) that allow the user to deselect the device when desired. If any one of these three is not asserted when ADV/LD is low, no new memory operation can be initiated. However, any pending data transfers (reads or writes) will be completed. The data bus will tri-state one cycle after chip is deselected or a write is initiated. The IDT71V3557/59 have an on-chip burst counter. In the burst mode, the IDT71V3557/59 can provide four cycles of data for a single address presented to the SRAM. The order of the burst sequence is defined by the LBO input pin. The LBO pin selects between linear and interleaved burst sequence. The ADV/LD signal is used to load a new external address (ADV/LD = LOW) or increment the internal burst counter (ADV/LD = HIGH). The IDT71V3557/59 SRAMs utilize IDT's latest high-performance CMOS process and are packaged in a JEDEC standard 14mm x 20mm 100-pin thin plastic quad flatpack (TQFP) as well as a 119 ball grid array (BGA) and a 165 fine pitch ball grid array (fBGA). 128K x 36, 256K x 18 memory configurations Supports high performance system speed - 100 MHz (7.5 ns Clock-to-Data Access) ZBTTM Feature - No dead cycles between write and read cycles Internally synchronized output buffer enable eliminates the need to control OE W (READ/WRITE) control pin Single R/W 4-word burst capability (Interleaved or linear) BW1 - BW4) control (May tie active) Individual byte write (BW Three chip enables for simple depth expansion 3.3V power supply (5%), 3.3V (5%) I/O Supply (VDDQ) Optional Boundary Scan JTAG Interface (IEEE 1149.1 complaint) Packaged in a JEDEC Standard 100-pin plastic thin quad flatpack (TQFP), 119 ball grid array (BGA) and 165 fine pitch ball grid array (fBGA) Description The IDT71V3557/59 are 3.3V high-speed 4,718,592-bit (4.5 Megabit) synchronous SRAMs organized as 128K x 36/256K x 18. They are designed to eliminate dead bus cycles when turning the bus around between reads and writes, or writes and reads. Thus they have been given the name ZBTTM, or Zero Bus Turnaround. Address and control signals are applied to the SRAM during one clock cycle, and on the next clock cycle the associated data cycle occurs, be Pin Description Summary A0-A 17 Address Inputs Input Synchronous CE1, CE2, CE2 Chip Enables Input Synchronous OE Output Enable Input Asynchronous R/W Read/Write Signal Input Synchronous CEN Clock Enable Input Synchronous BW1, BW2, BW3, BW4 Individual Byte Write Selects Input Synchronous CLK Clock Input N/A ADV/LD Advance burst address / Load new address Input Synchronous LBO Linear / Interleaved Burst Order Input Static TMS Test Mode Select Input Synchronous TDI Test Data Input Input Synchronous TCK Test Clock Input N/A TDO Test Data Output Output Synchronous TRST JTAG Reset (Optional) Input Asynchronous Input Synchronous I/O Synchronous ZZ Sleep Mode I/O0-I/O31, I/OP1-I/OP4 Data Input / Output VDD, VDDQ Core Power, I/O Power Supply Static VSS Ground Supply Static 5282 tbl 01 1 (c)2004 Integrated Device Technology, Inc. DECEMBER 2005 DSC-5282/08 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Pin Definitions (1) Symbol Pin Function I/O Active Description A0-A17 Address Inputs I N/A Synchronous Address inputs. The address register is triggered by a combination of the rising edge of CLK, ADV/ LD low, CEN low, and true chip enables. ADV/LD Advance / Load I N/A ADV/ LD is a synchronous input that is used to load the internal registers with new address and control when it is sampled low at the rising edge of clock with the chip selected. When ADV/ LD is low with the chip deselected, any burst in progress is terminated. When ADV/ LD is sampled high then the internal burst counter is advanced for any burst that was in progress. The external addresses are ignored when ADV/ LD is sampled high. R/ W Read / Write I N/A R/ W signal is a synchronous input that identifies whether the current load cycle initiated is a Read or Write access to the memory array. The data bus activity for the current cycle takes place one clock cycle later. CEN Clock Enable I LOW Sy nchronous Clock Enable Input. When CEN is sampled high, all other synchronous inputs, including clock are ignored and outputs remain unchanged. The effect of CEN sampled high on the device outputs is as if the low to high clock transition did not occur. For normal operation, CEN must be samp led low at rising edge of clock. BW1-BW4 Individual Byte Write Enables I LOW Synchronous byte write enables. Each 9-bit byte has its own active low byte write enable. On load write cycles (When R/W and ADV/ LD are sampled low) the appropriate byte write signal (BW1-BW4) must be valid. The byte write signal must also be valid on each cycle of a burst write. Byte Write signals are ignored when R/ W is sampled high. The ap propriate byte(s) of data are written into the device one cycle later. BW1-BW4 can all be tied low if always doing write to the entire 36-bit word. CE1, CE2 Chip Enables I LOW Synchronous active low chip enable. CE1 and CE2 are used with CE 2 to enable the IDT71V3557/59. (CE1 or CE2 sampled high or CE 2 sampled low) and ADV/LD low at the rising edge of clock, initiates a deselect cycle. The ZBTTM has a one cycle dese lect, i.e., the data bus will tri-state one clock cycle after deselect is initiated. CE 2 Chip Enable I HIGH Synchronous active high chip enable. CE 2 is used with CE1 and CE2 to enable the chip. CE 2 has inverted polarity but otherwise identical to CE1 and CE2. CLK Clock I N/A This is the clock input to the IDT71V3557/59. Except for OE, all timing references for the device are made with respect to the rising edge of CLK. I/O0-I/O31 I/OP1-I/OP4 Data Input/Output I/O N/A Data input/output (I/O) pins. The data input path is registered, triggered by the rising edge of CLK. The data output path is flow-through (no output register). LBO Linear Burst Order I LOW Burst order selection input. When LBO is high the Interleaved burst sequence is selected. When LBO is low the Linear burst sequence is selected. LBO is a static input, and it must not change during device operation.. OE Output Enable I LOW Asynchronous output enable. OE must be low to read data from the 71V3557/59. When OE is HIGH the I/O pins are in a high-impedance state. OE does not need to be actively controlled for read and write cycles. In normal operation, OE can be tied low. TMS Test Mode Select I N/A Gives input command for TAP controller. Sampled on rising edge of TDK. This pin has an internal pullup. TDI Test Data Input I N/A Serial input of registers placed between TDI and TDO. Sampled on rising edge of TCK. This pin has an internal pullup. TCK Test Clock I N/A Clock input of TAP controller. Each TAP event is clocked. Test inputs are captured on rising edge of TCK, while test outputs are driven from the falling edge of TCK. This pin has an internal pullup. TDO Test Data Output O N/A Serial output of registers placed between TDI and TDO. This output is active depending on the state of the TAP controller. TRST JTAG Reset (Optional) I LOW Optional Asynchronous JTAG reset. Can be used to reset the TAP controller, but not required. JTAG reset occurs automatically at power up and also rese ts using TMS and TCK per IEEE 1149.1. If not used TRST can be left floating. This pin has an internal pullup. ZZ Sleep Mode I HIGH Synchronous sleep mode input. ZZ HIGH will gate the CLK internally and power down the IDT71V3557/3559 to its lowest power consumption level. Data retention is guaranteed in Sleep Mode. This pin has an internal pulldown. V DD Power Supply N/A N/A 3.3V core power supply. VDDQ Power Supply N/A N/A 3.3V I/O Supply. V SS Ground N/A N/A Ground. 5282 tbl 02 NOTE: 1. All synchronous inputs must meet specified setup and hold times with respect to CLK. 6.42 2 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Functional Block Diagram 128K x 36 LBO Address A [0:16] 128K x 36 BIT MEMORY ARRAY D Q Address D Q Control CE1, CE2 CE2 R/W Input Register CEN ADV/LD BWx D DI Q DO Control Logic Clk Mux Clock Gate OE TMS TDI TCK TRST (optional) Sel Data I/O [0:31], I/O P[1:4] JTAG (SA Version) TDO 6.42 3 5282 drw 01 , IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Functional Block Diagram 256K x 18 LBO 256K x 18 BIT MEMORY ARRAY Address A [0:17] D Q Address D Q Control CE1, CE2 CE2 R/W Input Register CEN ADV/LD BWx D DI DO Control Logic Q Clk Mux Clock Gate OE Data I/O [0:15], I/O P[1:2] TMS TDI TCK TRST (optional) JTAG (SA Version) TDO Recommended DC Operating Conditions Symbol Parameter Min. Typ. Max. Unit VDD Core Supply Voltage 3.135 3.3 3.465 V VDDQ I/O Supply Voltage 3.135 3.3 3.465 V 0 0 0 V 2.0 ____ VDD + 0.3 2.0 ____ VSS Ground VIH Input High Voltage - Inputs VIH VIL Input High Voltage - I/O Input Low Voltage Sel (1) -0.3 ____ V (2) VDDQ + 0.3 0.8 V V 5282 tbl 04 NOTES: 1. VIL (min.) = -1.0V for pulse width less than tCYC/2, once per cycle. 2. VIH (max.) = +6.0V for pulse width less than t CYC/2, once per cycle. 6.42 4 5282 drw 01a , IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Recommended Operating Temperature and Supply Voltage Grade Temperature(1) VSS VDD VDDQ Commercial 0C to +70C 0V 3.3V5% 3.3V5% Industrial -40C to +85C 0V 3.3V5% 3.3V5% 5282 tbl 05 NOTES: 1. TA is the "instant on" case temperature. A6 A7 CE1 CE2 BW4 BW3 BW2 BW1 CE2 VDD VSS CLK R/W CEN OE ADV/LD NC(3) NC(3) A8 A9 Pin Configuration 128K x 36 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 I/OP3 I/O16 I/O17 VDDQ VSS I/O18 I/O19 I/O20 I/O21 VSS VDDQ I/O22 I/O23 VSS(1) VDD VDD(2) VSS I/O24 I/O25 VDDQ VSS I/O26 I/O27 I/O28 I/O29 VSS VDDQ I/O30 I/O31 I/OP4 1 80 2 79 3 78 77 4 5 6 76 75 7 74 8 73 9 72 71 10 11 70 12 69 13 68 14 67 15 66 16 65 64 17 18 63 19 62 20 61 21 60 22 59 23 24 58 57 25 56 26 55 27 54 53 28 29 I/OP2 I/O15 I/O14 VDDQ VSS I/O13 I/O12 I/O11 I/O10 VSS VDDQ I/O9 I/O8 VSS VSS(1) VDD VSS/ZZ(1,4) I/O7 I/O6 VDDQ VSS I/O5 I/O4 I/O3 I/O2 VSS VDDQ I/O1 I/O0 I/OP1 52 51 30 , 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 LBO A5 A4 A3 A2 A1 A0 NC NC VSS VDD NC NC A10 A11 A12 A13 A14 A15 A16 5282 drw 02 Top View 100 TQFP NOTES: 1. Pins 14, 64, and 66 do not have to be connected directly to VSS as long as the input voltage is < VIL. 2. Pin 16 does not have to be connected directly to VDD as long as the input voltage is > VIH. 3. Pins 83 and 84 are reserved for future 8M and 16M respectively. 4. Pin 64 supports ZZ (sleep mode) for the latest die revisions. 6.42 5 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Absolute Maximum Ratings (1) VDD VSS CLK R/W CEN OE ADV/LD NC(3) NC(3) A8 A9 CE2 NC NC BW2 BW1 CE2 A6 A7 CE1 Pin Configuration 256K x 18 Symbol 1 80 2 79 3 78 VDDQ VSS NC NC I/O8 I/O9 VSS VDDQ I/O10 I/O11 VSS(1) VDD VDD(2) VSS I/O12 I/O13 VDDQ VSS I/O14 I/O15 I/OP2 NC VSS VDDQ NC NC NC 4 77 5 76 6 75 7 74 8 73 9 72 10 71 11 70 12 69 13 68 14 67 15 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 A10 NC NC VDDQ VSS NC I/OP1 I/O7 I/O6 VSS VDDQ I/O5 I/O4 VSS VSS(1) VDD VSS/ZZ(1,4) I/O3 I/O2 VDDQ VSS I/O1 I/O0 NC NC VSS VDDQ NC NC NC LBO A5 A4 A3 A2 A1 A0 NC NC VSS VDD NC NC A11 A12 A13 A14 A15 A16 A17 5282 drw 02a Top View 100 TQFP NOTES: 1. Pins 14, 64, and 66 do not have to be connected directly to VSS as long as the input voltage is < VIL . 2. Pin 16 does not have to be connected directly to VDD as long as the input voltage is > VIH. 3. Pins 83 and 84 are reserved for future 8M and 16M respectively. 4. Pin 64 supports ZZ (sleep mode) for the latest die revisions. 100 TQFP Capacitance(1) (TA = +25C, F = 1.0MHZ) Symbol Parameter(1) CIN Input Capacitance CI/O I/O Capacitance -0.5 to +4.6 V VTERM(3,6) Terminal Voltage with Respect to GND -0.5 to VDD V VTERM(4,6) Terminal Voltage with Respect to GND -0.5 to VDD +0.5 V VTERM(5,6) Terminal Voltage with Respect to GND -0.5 to VDDQ +0.5 V Commercial Operating Temperature -0 to +70 o C Industrial Operating Temperature -40 to +85 o C TBIAS Temperature Under Bias -55 to +125 o C TSTG Storage Temperature -55 to +125 o C PT Power Dissipation 2.0 W IOUT DC Output Current 50 mA TA 5282 tbl 06 119 BGA Capacitance(1) (TA = +25C, F = 1.0MHZ) Conditions Max. Unit VIN = 3dV 5 pF Symbol VOUT = 3dV 7 pF CIN Input Capacitance CI/O I/O Capacitance 119 BGA Capacitance(1) CIN Input Capacitance CI/O I/O Capacitance Parameter(1) Conditions Max. Unit VIN = 3dV 7 pF VOUT = 3dV 7 pF 5282 tbl 07a (TA = +25C, F = 1.0MHZ) Parameter(1) (7) 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 terminals only. 3. VDDQ terminals only. 4. Input terminals only. 5. I/O terminals only. 6. This is a steady-state DC parameter that applies after the power supply has reached its nominal operating value. Power sequencing is not necessary; however, the voltage on any input or I/O pin cannot exceed VDDQ during power supply ramp up. 7. TA is the "instant on" case temperature. 5282 tbl 07 Symbol Unit Terminal Voltage with Respect to GND , 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 Commercial & Industrial Values VTERM(2) 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 NC NC NC Rating Conditions Max. Unit VIN = 3dV TBD pF VOUT = 3dV TBD pF 5282 tb l 07b NOTE: 1. This parameter is guaranteed by device characterization, but not production tested. 6.42 6 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Pin Configuration 128K x 36, 119 BGA 1 2 3 4 5 6 7 NC(3) A8 A16 VDDQ ADV/LD A9 CE2 NC A12 A15 NC A VDDQ A6 A4 B NC CE 2 A3 C NC A7 A2 VDD D I/O16 I/OP3 VSS NC VSS I/OP2 I/O15 E I/O17 I/O18 VSS CE1 VSS I/O13 I/O14 F VDDQ I/O19 VSS OE VSS I/O12 VDDQ G I/O20 I/O21 BW3 NC(3) BW 2 I/O11 I/O10 H I/O22 I/O23 VSS R/W VSS I/O9 I/O8 J VDDQ VDD VDD(2) VDD VSS(1) VDD VDDQ K I/O24 I/O26 VSS CLK VSS I/O6 I/O7 L I/O25 I/O27 BW4 NC BW1 I/O4 I/O5 M VDDQ I/O28 VSS CEN VSS I/O3 VDDQ N I/O29 I/O30 VSS A1 VSS I/O2 I/O1 P I/O31 I/OP4 VSS A0 VSS I/OP1 I/O0 R NC A5 LBO VDD A13 NC T NC NC A10 A11 VDDQ NC/TMS(4) NC/TDI(4) NC/TCK(4) U VSS(1) A14 NC/TDO(4) NC NC/TRST (4,5) NC/ZZ(6) VDDQ , 5282 drw 13A Top View Pin Configuration - 256K x 18, 119 BGA 1 2 3 4 5 6 7 A VDDQ A6 A4 NC(3) A8 A16 VDDQ B NC CE2 A3 ADV/LD A9 CE2 NC C NC A7 A2 VDD A13 A17 NC D I/O8 NC VSS NC VSS I/OP1 NC E NC I/O9 VSS CE1 VSS NC I/O7 F VDDQ NC VSS OE VSS I/O6 VDDQ G NC I/O10 BW2 NC(3) VSS NC I/O5 H I/O11 NC VSS R/W VSS I/O4 NC J VDDQ VDD VDD(2) VDD VSS(1) VDD VDDQ K NC I/O12 VSS CLK VSS NC I/O3 L I/O13 NC VSS NC BW1 I/O2 NC M VDDQ I/O14 VSS CEN VSS NC VDDQ N I/O15 NC VSS A1 VSS I/O1 NC P NC I/OP2 VSS A0 VSS NC I/O0 R NC A5 LBO VDD VSS(1) A12 NC T NC A10 A15 NC A14 A11 NC/ZZ(6) U VDDQ NC/TMS(4) NC/TDI(4) NC/TCK(4) NC/TDO(4) NC/TRST(4,5) VDDQ , 5282 drw 13B Top View NOTES: 1. R5 and J5 do not have to be directly connected to VSS as long as the input voltage is < VIL. 2. J3 does not have to be directly connected directly to VDD as long as the input voltage is VIH. 3. G4 and A4 are reserved for future 8M and 16M respectively. 4. These pins are NC for the "S" version and the JTAG signal listed for the "SA" version. 5. TRST is offered as an optional JTAG reset if requested in the application. If not needed, can be left floating and will internally be pulled to VDD. 6. Pin T7 supports ZZ (sleep mode) for the latest die revisions. 6.42 7 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Pin Configuration 128K x 36, 165 fBGA A 1 2 3 4 5 6 7 8 9 10 11 NC(3) A7 CE1 BW3 BW2 CE2 CEN ADV/LD NC(3) A8 NC (3) B NC A6 CE2 BW4 BW1 CLK R/W OE NC A9 NC(3) C I/OP3 NC VDDQ V SS V SS VSS VSS VSS VDDQ NC I/OP2 D I/O17 I/O16 VDDQ V DD V SS VSS VSS VDD VDDQ I/O15 I/O14 E I/O19 I/O18 VDDQ V DD V SS VSS VSS VDD VDDQ I/O13 I/O12 F I/O21 I/O20 VDDQ V DD V SS VSS VSS VDD VDDQ I/O11 I/O10 G I/O23 I/O22 VDDQ V DD V SS VSS VSS VDD VDDQ I/O9 I/O8 H VSS (1) (2) NC V DD V SS VSS VSS VDD NC NC NC/ZZ(6) J I/O25 I/O24 VDDQ V DD V SS VSS VSS VDD VDDQ I/O7 I/O6 K I/O27 I/O26 VDDQ V DD V SS VSS VSS VDD VDDQ I/O5 I/O4 L I/O29 I/O28 VDDQ V DD V SS VSS VSS VDD VDDQ I/O3 I/O2 M I/O31 I/O30 VDDQ V DD V SS VSS VSS VDD VDDQ I/O1 I/O0 N I/OP4 NC VDDQ V SS NC/ TRST(4, 5) NC VSS (1) VSS VDDQ NC I/OP1 P NC NC(3) A5 A2 NC/TDI(4) A1 NC/TDO(4) A10 A13 A14 NC R LBO (3) A0 (4) A11 A12 A15 A16 VDD NC A4 A3 NC/TMS (4) NC/TCK 5282 tbl 25 Pin Configuration - 256K x 18, 165 fBGA 1 2 3 4 5 6 7 8 9 10 11 A NC(3) A7 CE1 BW2 NC CE2 CEN ADV/LD NC(3) A8 A10 B NC A6 CE2 NC BW1 CLK R/W OE NC(3) A9 NC(3) C NC NC VDDQ VSS V SS VSS VSS VSS VDDQ NC I/OP1 D NC I/O8 VDDQ VDD V SS VSS VSS VDD VDDQ NC I/O7 E NC I/O9 VDDQ VDD V SS VSS VSS VDD VDDQ NC I/O6 F NC I/O10 VDDQ VDD V SS VSS VSS VDD VDDQ NC I/O5 G NC I/O11 VDDQ VDD V SS VSS VSS VDD VDDQ NC I/O4 H Vss (1) VDD(2) NC VDD V SS VSS VSS VDD NC NC NC/ZZ(6) J I/O12 NC VDDQ VDD V SS VSS VSS VDD VDDQ I/O3 NC K I/O13 NC VDDQ VDD V SS VSS VSS VDD VDDQ I/O2 NC L I/O14 NC VDDQ VDD V SS VSS VSS VDD VDDQ I/O1 NC M I/O15 NC VDDQ VDD V SS VSS VSS VDD VDDQ I/O0 NC N I/OP2 NC (3) VDDQ VSS NC/ TRST (4, 5) (4) NC VSS (1) VSS VDDQ NC NC (4) P NC NC A5 A2 NC/TDI A1 NC/TDO A 11 A14 A 15 NC R LBO NC(3) A4 A3 NC/TMS(4) A0 NC/TCK (4) A12 A13 A 16 A17 5282 tbl 25a NOTES: 1. H1 and N7 do not have to be directly connected to V SS as long as the input voltage is < VIL. 2. H2 does not have to be directly connected directly to VDD as long as the input voltage is VIH. 3. A9, B9, B11, A1, R2, and P2 are reserved for future 9M, 18M, 36M, 72M, 144M, and 288M respectively. 4. These pins are NC for the "S" version and the JTAG signal listed for the "SA" version. 5. TRST is offered as an optional JTAG reset if requested in the application. If not needed, can be left floating and will internally be pulled to VDD. 6. Pin H11 supports ZZ (sleep mode) for the latest die revisions. 6.42 8 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Synchronous Truth Table (1) CEN R/W CE1, CE2(5) ADV/ LD BWx ADDRESS USED PREVIOUS CYCLE CURRENT CYCLE I/O (One cycle later) L L L L Valid External X LOAD WRITE D(7) L H L L X External X LOAD READ Q(7) L X X H Valid Internal LOAD WRITE / BURST WRITE BURST WRITE (Advance burst counter)(2) D(7) L X X H X Internal LOAD READ / BURST READ BURST READ (Advance burst counter)(2) Q(7) L X H L X X X DESELECT or STOP(3) HIZ L X X H X X DESELECT / NOOP NOOP HIZ H X X X X X (4) X SUSPEND Previous Value 5282 tbl 08 NOTES: 1. L = VIL, H = VIH, X = Don't Care. 2. When ADV/LD signal is sampled high, the internal burst counter is incremented. The R/W signal is ignored when the counter is advanced. Therefore the nature of the burst cycle (Read or Write) is determined by the status of the R/W signal when the first address is loaded at the beginning of the burst cycle. 3. Deselect cycle is initiated when either (CE1, or CE2 is sampled high or CE2 is sampled low) and ADV/LD is sampled low at rising edge of clock. The data bus will tri-state one cycle after deselect is initiated. 4. When CEN is sampled high at the rising edge of clock, that clock edge is blocked from propogating through the part. The state of all the internal registers and the I/ Os remains unchanged. 5. To select the chip requires CE1 = L, CE2 = L and CE2 = H on these chip enable pins. The chip is deselected if any one of the chip enables is false. 6. Device Outputs are ensured to be in High-Z during device power-up. 7. Q - data read from the device, D - data written to the device. Partial Truth Table for Writes (1) R/W BW1 BW2 BW3(3) BW4(3) READ H X X X X WRITE ALL BYTES L L L L L L L H H H OPERATION WRITE BYTE 1 (I/O[0:7], I/OP1)(2) (2) WRITE BYTE 2 (I/O[8:15], I/OP2) L H L H H (2,3) WRITE BYTE 3 (I/O[16:23], I/OP3) L H H L H WRITE BYTE 4 (I/O[24:31], I/OP4)(2,3) L H H H L NO WRITE L H H H H 5282 tbl 09 NOTES: 1. L = VIL, H = VIH, X = Don't Care. 2. Multiple bytes may be selected during the same cycle. 3. N/A for x18 configuration. 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 NOTE: 1. Upon completion of the Burst sequence the counter wraps around to its initial state and continues counting. 6.42 9 5282 tbl 10 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges 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 Fourth Address (1) 1 1 0 0 0 1 1 0 5282 tbl 11 NOTE: 1. Upon completion of the Burst sequence the counter wraps around to its initial state and continues counting. Functional Timing Diagram (1) CYCLE n+29 n+30 n+31 n+32 n+33 n+34 n+35 n+36 n+37 A29 A30 A31 A32 A33 A34 A35 A36 A37 C29 C30 C31 C32 C33 C34 C35 C36 C37 D/Q28 D/Q29 D/Q30 D/Q31 D/Q32 D/Q33 D/Q34 D/Q35 D/Q36 CLOCK ADDRESS (A0 - A16) (2) CONTROL(2) (R/W, ADV/LD, BWx) (2) DATA I/O [0:31], I/O P[1:4] 5282 drw 03 NOTES: 1. This assumes CEN, CE1, CE2 and CE2 are all true. 2. All Address, Control and Data_In are only required to meet set-up and hold time with respect to the rising edge of clock. Data_Out is valid after a clock-to-data delay from the rising edge of clock. 6.42 10 , IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Device Operation - Showing Mixed Load, Burst, Deselect and NOOP Cycles (2) Cycle Address R/W ADV/ LD CE1(1) CEN BWx OE I/O Comments n A0 H L L L X X D1 Load read n+1 X X H X L X L Q0 Burst read n+2 A1 H L L L X L Q0+1 Load read n+3 X X L H L X L Q1 Deselect or STOP n+4 X X H X L X X Z NOOP n+5 A2 H L L L X X Z Load read n+6 X X H X L X L Q2 Burst read n+7 X X L H L X L Q2+1 n+8 A3 L L L L L X Z Load write n+9 X X H X L L X D3 Burst write n+10 A4 L L L L L X D3+1 Load write n+11 X X L H L X X D4 Deselect or STOP n+12 X X H X L X X Z NOOP n+13 A5 L L L L L X Z Load write n+14 A6 H L L L X X D5 Load read n+15 A7 L L L L L L Q6 Load write n+16 X X H X L L X D7 Burst write n+17 A8 H L L L X X D7+1 Load read n+18 X X H X L X L Q8 Burst read n+19 A9 L L L L L L Q8+1 Load write Deselect or STOP 5282 tbl 12 NOTES: 1. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 2. H = High; L = Low; X = Don't Care; Z = High Impedence. 6.42 11 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Read Operation (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 H L L L X X X Address and Control meet setup n+1 X X X X X X L Q0 Contents of Address A0 Read Out NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE 2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 5282 tbl 13 Burst Read Operation (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 H L L L X X X Address and Control meet setup n+1 X X H X L X L Q0 Address A 0 Read Out, Inc. Count n+2 X X H X L X L Q0+1 Address A 0+1 Read Out, Inc. Count n+3 X X H X L X L Q0+2 Address A 0+2 Read Out, Inc. Count n+4 X X H X L X L Q0+3 Address A 0+3 Read Out, Load A1 n+5 A1 H L L L X L Q0 Address A 0 Read Out, Inc. Count n+6 X X H X L X L Q1 Address A 1 Read Out, Inc. Count n+7 A2 H L L L X L Q1+1 Address A 1+1 Read Out, Load A2 NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. Write Operation 5282 tbl 14 (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 L L L L L X X Address and Control meet setup n+1 X X X X L X X D0 Write to Address A 0 NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. Burst Write Operation 5282 tbl 15 (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 L L L L L X X Address and Control meet setup n+1 X X H X L L X D0 Address A 0 Write, Inc. Count n+2 X X H X L L X D0+1 Address A 0+1 Write, Inc. Count n+3 X X H X L L X D0+2 Address A 0+2 Write, Inc. Count n+4 X X H X L L X D0+3 Address A 0+3 Write, Load A1 n+5 A1 L L L L L X D0 Address A 0 Write, Inc. Count n+6 X X H X L L X D1 Address A 1 Write, Inc. Count n+7 A2 L L L L L X D1+1 Address A 1+1 Write, Load A2 NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 6.42 12 5282 tbl 16 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Read Operation with Clock Enable Used (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 H L L L X X X AddressA 0 and Control meet setup n+1 X X X X H X X X Clock n+1 Ignored n+2 A1 H L L L X L Q0 Address A 0 Read out, Load A1 n+3 X X X X H X L Q0 Clock Ignored. Data Q0 is on the bus. n+4 X X X X H X L Q0 Clock Ignored. Data Q0 is on the bus. n+5 A2 H L L L X L Q1 Address A 1 Read out, Load A 2 n+6 A3 H L L L X L Q2 Address A 2 Read out, Load A 3 n+7 A4 H L L L X L Q3 Address A 3 Read out, Load A 4 NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 5282 tbl 17 Write Operation with Clock Enable Used (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O Comments n A0 L L L L L X X Address A 0 and Control meet setup. n+1 X X X X H X X X Clock n+1 Ignored. n+2 A1 L L L L L X D0 Write data D0, Load A1. n+3 X X X X H X X X Clock Ignored. n+4 X X X X H X X X Clock Ignored. n+5 A2 L L L L L X D1 Write Data D1, Load A2 n+6 A3 L L L L L X D2 Write Data D2, Load A3 n+7 A4 L L L L L X D3 Write Data D3, Load A4 5282 tbl 18 NOTES: 1. H = High; L = Low; X = Don't Care; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 6.42 13 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Read Operation with Chip Enable Used (1) Cycle Address R/W ADV/ LD CE1(2) CEN BWx OE I/O(3) Comments n X X L H L X X ? Deselected. n+1 X X L H L X X Z Deselected. n+2 A0 H L L L X X Z Address A 0 and Control meet setup. n+3 X X L H L X L Q0 Address A 0 read out, Deselected. n+4 A1 H L L L X X Z Address A 1 and Control meet setup. n+5 X X L H L X L Q1 Address A 1 read out, Deselected. n+6 X X L H L X X Z Deselected. n+7 A2 H L L L X X Z Address A 2 and Control meet setup. n+8 X X L H L X L Q2 Address A 2 read out, Deselected. n+9 X X L H L X X Z Deselected. NOTES: 1. H = High; L = Low; X = Don't Care; ? = Don't Know; Z = High Impedance. 2. CE2 timing transition is identical to CE1 signal. CE2 timing transition is identical but inverted to the CE1 and CE2 signals. 3. Device outputs are ensured to be in High-Z during device power-up. 5282 tbl 19 Write Operation with Chip Enable Used (1) Cycle Address R/ W ADV/LD CE(2) CEN BWx OE I/O Comments n X X L H L X X ? Deselected. n+1 X X L H L X X Z Deselected. n+2 A0 L L L L L X Z Address A0 and Control meet setup n+3 X X L H L X X D0 Data D0 Write In, Deselected. n+4 A1 L L L L L X Z Address A1 and Control meet setup n+5 X X L H L X X D1 Data D1 Write In, Deselected. n+6 X X L H L X X Z Deselected. n+7 A2 L L L L L X Z Address A2 and Control meet setup n+8 X X L H L X X D2 Data D2 Write In, Deselected. n+9 X X L H L X X Z Deselected. NOTES: 1. H = High; L = Low; X = Don't Care; ? = Don't Know; Z = High Impedance. 2. CE = L is defined as CE1 = L, CE2 = L and CE2 = H. CE = H is defined as CE1 = H, CE2 = H or CE2 = L. 6.42 14 5282 tbl 20 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges DC Electrical Characteristics Over the Operating Temperature and Supply Voltage Range (VDD = 3.3V +/-5%) Symbol Parameter Test Conditions Min. Max. Unit |ILI| Input Leakage Current VDD = Max., VIN = 0V to V DD ___ 5 A |ILI| LBO, JTAG and ZZ Input Leakage Current(1) VDD = Max., VIN = 0V to V DD ___ 30 A |ILO| Output Leakage Current VOUT = 0V to V CC ___ 5 A 0.4 V ___ V VOL Output Low Voltage IOL = +8mA, VDD = Min. ___ VOH Output High Voltage IOH = -8mA, VDD = Min. 2.4 5282 tbl 21 NOTE: 1. The LBO, JTAG and ZZ pins will be internally pulled to VDD and ZZ will be internally pulled to VSS if it is not actively driven in the application. DC Electrical Characterics Over the Operating Temperature and Supply Voltage Range (1) (VDD = 3.3V +/-5%) 7.5ns Symbol Parameter Test Conditions 8ns 8.5ns Com'l Only Com'l Ind Com'l Ind Unit IDD Operating Power Supply Current Device Selected, Outputs Open, ADV/LD = X, VDD = Max., V IN > VIH or < VIL, f = fMAX(2) 275 250 260 225 235 mA ISB1 CMOS Standby Power Supply Current Device Deselected, Outputs Open, V DD = Max., VIN > VHD or < VLD, f = 0(2,3) 40 40 45 40 45 mA ISB2 Clock Running Power Supply Current Device Deselected, Outputs Open, V DD = Max., VIN > VHD or < VLD, f = fMAX(2,3) 105 100 110 95 105 mA ISB3 Idle Power Supply Current Device Selected, Outputs Open, CEN > VIH, VDD = Max., V IN > VHD or < VLD, f = fMAX(2,3) 40 40 45 40 45 mA 5282 tbl 22 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; f=0 means no input lines are changing. 3. For I/Os VHD = VDDQ - 0.2V, VLD = 0.2V. For other inputs VHD = VDD - 0.2V, VLD = 0.2V. AC Test Loads AC Test Conditions (VDDQ = 3.3V) VDDQ/2 Input Pulse Levels 50 I/O Z0 = 50 6 , 5282 drw 04 Figure 1. AC Test Load 5 Input Rise/Fall Times 2ns Input Timing Reference Levels 1.5V Output Reference Levels 1.5V Output Load 4 0 to 3V Figure 1 5282 tbl 23 tCD 3 (Typical, ns) 2 1 20 30 50 80 100 Capacitance (pF) 200 5282 drw 05 , Figure 2. Lumped Capacitive Load, Typical Derating 6.42 15 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges AC Electrical Characteristics (VDD = 3.3V +/-5%, Commercial and Industrial Temperature Ranges) 8ns 7.5ns(5) Symbol Parameter 8.5ns Min. Max. Min. Max. Min. Max. Unit tCYC Clock Cycle Time 10 ____ 10.5 ____ 11 ____ ns tCH(1) Clock High Pulse Width 2.5 ____ 2.7 ____ 3.0 ____ ns tCL(1) Clock Low Pulse Width 2.5 ____ 2.7 ____ 3.0 ____ ns ____ 7.5 ____ 8 ____ 8.5 ns Output Parameters tCD Clock High to Valid Data tCDC Clock High to Data Change 2 ____ 2 ____ 2 ____ ns tCLZ(2,3,4) Clock High to Output Active 3 ____ 3 ____ 3 ____ ns tCHZ(2,3,4) Clock High to Data High-Z ____ 5 ____ 5 ____ 5 ns tOE Output Enable Access Time ____ 5 ____ 5 ____ 5 ns 0 ____ 0 ____ 0 ____ ns ____ 5 ____ 5 ____ 5 ns 2.0 ____ 2.0 ____ 2.0 ____ ns 2.0 ____ 2.0 ____ ns 2.0 ____ 2.0 ____ ns ns tOLZ(2,3) Output Enable Low to Data Active tOHZ(2,3) Output Enable High to Data High-Z Set Up Times tSE Clock Enable Setup Time tSA Address Setup Time 2.0 ____ tSD Data In Setup Time 2.0 ____ tSW Read/Write (R/W ) Setup Time 2.0 ____ 2.0 ____ 2.0 ____ tSADV Advance/Load (ADV/ LD) Setup Time 2.0 ____ 2.0 ____ 2.0 ____ ns tSC Chip Enable/Select Setup Time 2.0 ____ 2.0 ____ 2.0 ____ ns tSB Byte Write Enable (BWx) Setup Time 2.0 ____ 2.0 ____ 2.0 ____ ns tHE Clock Enable Hold Time 0.5 ____ 0.5 ____ 0.5 ____ ns tHA Address Hold Time 0.5 ____ 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns Hold Times tHD Data In Hold Time 0.5 ____ tHW Read/Write (R/W ) Hold Time 0.5 ____ 0.5 ____ 0.5 ____ ns tHADV Advance/Load (ADV/ LD) Hold Time 0.5 ____ 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns 0.5 ____ 0.5 ____ ns tHC Chip Enable/Select Hold Time 0.5 ____ tHB Byte Write Enable (BWx) Hold Time 0.5 ____ 5282 tbl 24 NOTES: 1. Measured as HIGH above 0.6VDDQ and LOW below 0.4VDDQ. 2. Transition is measured 200mV from steady-state. 3. These parameters are guaranteed with the AC load (Figure 1) by device characterization. They are not production tested. 4. To avoid bus contention, the output buffers are designed such that t CHZ (device turn-off) is about 1ns faster than tCLZ (device turn-on) at a given temperature and voltage. The specs as shown do not imply bus contention because tCLZ is a Min. parameter that is worse case at totally different test conditions (0 deg. C, 3.465V) than tCHZ, which is a Max. parameter (worse case at 70 deg. C, 3.135V). 5. Commercial temperature range only. 6.42 16 6.42 17 DATAOUT OE BW1 - BW4 tCLZ A1 tHA tHW tHE tSC tCD tHC A2 tSA tSW Q(A1) Read tSADV tSE Read Q(A2) tCDC tHADV tCH Q(A2+1) tCD tCL Burst Read Q(A2+2) Q(A2+3) (CEN high, eliminates current L-H clock edge) tCDC Q(A2+3) Q(A2) (Burst Wraps around to initial state) tCHZ , NOTES: 1. Q (A1) represents the first output from the external address A1. Q (A2) represents the first output from the external address A2; Q (A2+1) represents the next output data in the burst sequence of the base address A2, etc. where address bits A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. 2. CE2 timing transitions are identical but inverted to the CE1 and CE2 signals. For example, when CE1 and CE2 are LOW on this waveform, CE2 is HIGH. 3. Burst ends when new address and control are loaded into the SRAM by sampling ADV/LD LOW. 4. R/W is don't care when the SRAM is bursting (ADV/LD sampled HIGH). The nature of the burst access (Read or Write) is fixed by the state of the R/W signal when new address and control are loaded into the SRAM. CE1, CE2(2) ADDRESS R/W ADV/LD CEN CLK tCYC 5282 drw 06 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Read Cycle (1,2,3,4) . 6.42 18 B(A1) Write tHW tHC D(A1) tSD tHD tHB B(A2) tSB tSC tHA A2 tSA tSW tHE Write D(A2) B(A2+1) tHADV tCH tHD D(A2+1) tSD B(A2+2) tCL (CEN high, eliminates current L-H clock edge) Burst Write D(A2+2) B(A2+3) D(A2+3) (Burst Wraps around to initial state) B(A2) D(A2) 5282 drw 07 . , NOTES: 1. D (A1) represents the first input to the external address A1. D (A2) represents the first input to the external address A2; D (A2+1) represents the next input data in the burst sequence of the base address A2, etc. where address bits A0 and A1 are advancing for the four word burst in the sequence defined by the state of the LBO input. 2. CE2 timing transitions are identical but inverted to the CE1 and CE2 signals. For example, when CE1 and CE2 are LOW on this waveform, CE2 is HIGH. 3. Burst ends when new address and control are loaded into the SRAM by sampling ADV/LD LOW. 4. R/W is don't care when the SRAM is bursting (ADV/LD sampled HIGH). The nature of the burst access (Read or Write) is fixed by the state of the R/W signal when new address and control are loaded into the SRAM. 5. Individual Byte Write signals (BWx) must be valid on all write and burst-write cycles. A write cycle is initiated when R/W signal is sampled LOW. The byte write information comes in one cycle before the actual data is presented to the SRAM. DATAIN OE BW1 - BW4 A1 tSADV tSE Timing Waveform of Write Cycles CE1, CE2(2) ADDRESS R/W ADV/LD CEN CLK tCYC IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges (1,2,3,4,5) 6.42 19 A1 tCD t HW tHE t HC tCHZ tHB B(A2) tSB tSC tHA A2 t SA tSW Q(A1) Read tSADV t SE Write A3 tCLZ D(A2) tSD tHD tHADV t CH Read Q(A3) tCDC B(A4) A4 t CL Write D(A4) B(A5) A5 Write D(A5) A6 Read Q(A6) A7 Read Q(A7) B(A8) A8 , D(A8) A9 5282 drw 08 Write NOTES: 1. Q (A1) represents the first output from the external address A 1. D (A 2) represents the input data to the SRAM corresponding to address A2. 2. CE2 timing transitions are identical but inverted to the CE1 and CE2 signals. For example, when CE1 and CE2 are LOW on this waveform, CE2 is HIGH. 3. Individual Byte Write signals (BWx) must be valid on all write and burst-write cycles. A write cycle is initiated when R/W signal is sampled LOW. The byte write information comes in one cycle before the actual data is presented to the SRAM. DATAOUT DATAIN OE BW1 - BW4 CE1, CE2(2) ADDRESS R/W ADV/LD CEN CLK tCYC IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of Combined Read and Write Cycles (1,2,3) . 6.42 20 tCD tCLZ A1 Q(A1) tSE tSADV tHE tHA tHW tHC Q(A1) tCDC tCHZ tHB B(A2) tSB tSC A2 tSA tSW tCH tHADV tCL tCD D(A2) tSD tHD A3 Q(A3) tCDC A4 , A5 5282 drw 09 Q(A4) NOTES: 1. Q (A1) represents the first output from the external address A 1. D (A 2) represents the input data to the SRAM corresponding to address A2. 2. CE2 timing transitions are identical but inverted to the CE1 and CE2 signals. For example, when CE1 and CE2 are LOW on this waveform, CE2 is HIGH. 3. CEN when sampled high on the rising edge of clock will block that L-H transition of the clock from propogating into the SRAM. The part will behave as if the L-H clock transition did not occur. All internal registers in the SRAM will retain their previous state. 4. Individual Byte Write signals (BWx) must be valid on all write and burst-write cycles. A write cycle is initiated when R/W signal is sampled LOW. The byte write information comes in one cycle before the actual data is presented to the SRAM. DATAOUT DATAIN OE BW1 - BW4 CE1, CE2(2) ADDRESS R/W ADV/LD CEN CLK tCYC IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of CEN Operation (1,2,3,4) . 6.42 21 tCD tCLZ A1 tSADV tSC Q(A1) tHW tHE tHC tHA A2 tSA tSW tSE tCHZ tCDC Q(A2) tHADV tCH tHB B(A3) tSB A3 tCL D(A3) tSD tHD A4 Q(A4) A5 , 5282 drw 10 Q(A5) NOTES: 1. Q (A1) represents the first output from the external address A1. D (A3) represents the input data to the SRAM corresponding to address A3 etc. 2. CE2 timing transitions are identical but inverted to the CE1 and CE2 signals. For example, when CE1 and CE2 are LOW on this waveform, CE2 is HIGH. 3. When either one of the Chip enables (CE1, CE2, CE2) is sampled inactive at the rising clock edge, a deselect cycle is initiated. The data-bus tri-states one cycle after the initiation of the deselect cycle. This allows for any pending data transfers (reads or writes) to be completed. 4. Individual Byte Write signals (BWx) must be valid on all write and burst-write cycles. A write cycle is initiated when R/W signal is sampled LOW. The byte write information comes in one cycle before the actual data is presented to the SRAM. DATAOUT DATAIN OE BW1 - BW4 CE1, CE2(2) ADDRESS R/W ADV/LD CEN CLK tCYC IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of CS Operation (1,2,3,4) . IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges JTAG Interface Specification (SA Version only) tJF tJCL tJCYC tJR tJCH TCK Device Inputs(1)/ TDI/TMS tJS Device Outputs(2)/ TDO tJDC tJH tJRSR tJCD TRST(3) x M5282 drw 01 tJRST NOTES: 1. Device inputs = All device inputs except TDI, TMS and TRST. 2. Device outputs = All device outputs except TDO. 3. During power up, TRST could be driven low or not be used since the JTAG circuit resets automatically. TRST is an optional JTAG reset. JTAG AC Electrical Characteristics(1,2,3,4) Symbol Parameter Min. Max. Units ns tJCYC JTAG Clock Input Period 100 ____ tJCH JTAG Clock HIGH 40 ____ ns tJCL JTAG Clock Low 40 ____ ns tJR JTAG Clock Rise Time ____ 5(1) tJF JTAG Clock Fall Time ____ tJRST JTAG Reset tJRSR tJCD Scan Register Sizes Register Name Bit Size Instruction (IR) 4 ns Bypass (BYR) 1 5(1) ns JTAG Identification (JIDR) 50 ____ ns Boundary Scan (BSR) JTAG Reset Recovery 50 ____ ns JTAG Data Output ____ 20 ns ns ns tJDC JTAG Data Output Hold 0 ____ tJS JTAG Setup 25 ____ tJH JTAG Hold 25 ____ 32 Note (1) I5282 tbl 03 NOTE: 1. The Boundary Scan Descriptive Language (BSDL) file for this device is available by contacting your local IDT sales representative. ns I5282 tbl 01 NOTES: 1. Guaranteed by design. 2. AC Test Load (Fig. 1) on external output signals. 3. Refer to AC Test Conditions stated earlier in this document. 4. JTAG operations occur at one speed (10MHz). The base device may run at any speed specified in this datasheet. 6.42 22 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges JTAG Identification Register Definitions (SA Version only) Instruction Field Value Revision Number (31:28) Description 0x2 IDT Device ID (27:12) 0x209, 0x20B IDT JEDEC ID (11:1) 0x33 ID Register Indicator Bit (Bit 0) Reserved for version number. Defines IDT part number 71V3557SA and 71V3559SA, respectively. Allows unique identification of device vendor as IDT. 1 Indicates the presence of an ID register. I5282 tbl 02 Available JTAG Instructions Instruction Description OPCODE EXTEST Forces contents of the boundary scan cells onto the device outputs (1). Places the boundary scan register (BSR) between TDI and TDO. 0000 SAMPLE/PRELOAD Places the boundary scan register (BSR) between TDI and TDO. SAMPLE allows data from device inputs(2) and outputs(1) to be captured in the boundary scan cells and shifted serially through TDO. PRELOAD allows data to be input serially into the boundary scan cells via the TDI. 0001 DEVICE_ID Loads the JTAG ID register (JIDR) with the vendor ID code and places the register between TDI and TDO. 0010 HIGHZ Places the bypass register (BYR) between TDI and TDO. Forces all device o utput drivers to a High-Z state. 0011 RESERVED RESERVED RESERVED 0100 Several combinations are reserved. Do not use codes other than those identified for EXTEST, SAMPLE/PRELOAD, DEVICE_ID, HIGHZ, CLAMP, VALIDATE and BYPASS instructions. RESERVED CLAMP 0101 0110 0111 Uses BYR. Forces contents of the boundary scan cells onto the device outputs. Places the byp ass registe r (BYR) between TDI and TDO. RESERVED 1000 1001 RESERVED 1010 Same as above. RESERVED 1011 RESERVED 1100 VALIDATE Automatically loaded into the instruction register whenever the TAP controller passes through the CAPTURE-IR state. The lower two bits '01' are mand ated by the IEEE std. 1149.1 specification. 1101 RESERVED Same as above. 1110 BYPASS The BYPASS instruction is used to truncate the boundary scan register as a single bit in length. 1111 I5282 tbl 04 NOTES: 1. Device outputs = All device outputs except TDO. 2. Device inputs = All device inputs except TDI, TMS, and TRST. 6.42 23 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges 100-Pin Thin Quad Plastic Flatpack (TQFP) Package Diagram Outline 6.42 24 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges 119 Ball Grid Array (BGA) Package Diagram Outline 6.42 25 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges 165 Fine Pitch Ball Grid Array (fBGA) Package Diagram Outline 6.42 26 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Timing Waveform of OE Operation (1) OE tOE tOHZ DATA Out tOLZ Q Q , 5282 drw 11 NOTE: 1. A read operation is assumed to be in progress. Ordering Information IDT XXXX XX XX XX Device Type Power Speed Package X X Process/ Temperature Range Blank Commercial (0C to +70C) I Industrial (-40C to +85C) G Restricted Hazardous Substance Device PF** BG BQ 100-Pin Plastic Thin Quad Flatpack (TQFP) 119 Ball Grid Array (BGA) 165 Fine Pitch Ball Grid Array (fBGA) 75* 80 85 Access time (tCD) in tenths of nanoseconds S SA Standard Power Standard Power with JTAG Interface , IDT71V3557 128Kx36 Flow-Through ZBT SRAM with 3.3V I/O IDT71V3559 256Kx18 Flow-Through ZBT SRAM with 3.3V I/O 5282 drw 12 *C om m ercial tem perature range only. ** JTA G (S A version) is not available with 100-pin TQFP package 6.42 27 IDT71V3557, IDT71V3559, 128K x 36, 256K x 18, 3.3V Synchronous SRAMs with ZBTTM Feature, 3.3V I/O, Burst Counter, and Flow-Through Outputs Commercial and Industrial Temperature Ranges Datasheet Document History 6/30/99 8/23/99 12/31/99 05/02/00 Pg. 5, 6 Pg. 7 Pg. 15 Pg. 21 Pg. 23 Pg. 5, 14, 15, 22 Pg. 5,6 Pg. 5,6,7 Pg. 6 Pg. 21 05/26/00 07/26/00 Pg. 23 Pg. 5-8 Pg. 8 Pg. 23 10/25/00 05/20/02 10/15/04 Pg. 8 Pg. 1-8,15,22,23,27 Pg. 7 12/07/05 Pg. 27 Updated to new format Added Pin 64 to Note 1 and changed Pins 38, 42, and 43 to DNU Changed U2-U6 to DNU Improved tCH, tCL; revised tCLZ Added BGA package diagrams Added Datasheet Document History Added Industrial Temperature range offerings Insert clarification note to Recommended OperatingTemperature and Absolute Max ratings tables Clarify note on TQFP and BGA pin configurations; corrected typo in pinout Add BGA capacitance table Add TQFP Package Diagram Outline Add new package offering 13 x 15mm 165 fBGA Correct 119 BGA Package Diagram Outline Add ZZ sleep mode reference note to TQFP, BG119 and BQ165 Update BQ165 pinout Update BG119 pinout package diagram dimensions Remove preliminary status Add reference note to pin N5 on BQ165 pinout, reserved for JTAG TRST Added JTAG "SA" version functionality and updated ZZ pin descriptions and notes. Updated pin configuration for the 119 BGA - reordered I/O signals on P6, P7 (128K x 36) and P7, N6, L6, K7, H6, G7, F6, E7, D6 (256K x 18). Added "Restricted hazardous substance device" to ordering information. CORPORATE HEADQUARTERS 6024 Silver Creek Valley Rd San Jose, CA 95138 for SALES: 800-345-7015 or 408-284-8200 fax: 408-284-2775 www.idt.com The IDT logo is a registered trademark of Integrated Device Technology, Inc. for Tech Support: sramhelp@idt.com 800-345-7015 or 408/284-4555 ZBT and ZeroBus Turnaround are trademarks of Integrated Device Technology, Inc. and the architecture is supported by Micron Technology and Motorola Inc. 6.42 28