IDT70V5388S166BCI

3.3V 64/32K X 18 SYNCHRONOUS FOURPORT™ STATIC RAM Features ◆ ◆ ◆ IDT70V5388/78 ◆ ◆ ◆ ◆ ◆ ◆ ◆ True four-ported memory cells which allow simultaneous access of the same memory location Synchronous Pipelined device – 64/32K x 18 organization Pipelined output mode allows fast 200MHz operation High Bandwidth up to 14 Gbps (200MHz x 18 bits wide x 4 ports) LVTTL I/O interface High-speed clock to data access 3.0ns (max.) 3.3V Low operating power Interrupt flags for message passing Width and depth expansion capabilities ◆ ◆ ◆ ◆ ◆ ◆ ◆ ◆ ◆ Counter wrap-around control – Internal mask register controls counter wrap-around – Counter-Interrupt flags to indicate wrap-around Counter readback on address lines Mask register readback on address lines Global Master reset for all ports Dual Chip Enables on all ports for easy depth expansion Separate upper-word and lower-word controls on all ports 272-BGA package (27mm x 27mm 1.27mm ball pitch) and 256-BGA package (17mm x 17mm 1.0mm ball pitch) Commercial and Industrial temperature ranges JTAG boundary scan MBIST (Memory Built-In Self Test) controller Port - 1 Logic Block Diagram(2) R/WP1 UBP1 CE0P1 CE1P1 LBP1 OEP1 0 1 1 /0 I/O9P1 - I/O17P1 I/O0P1 - I/O8P1 Port 1 I/O Control TRST TMS TCK TDI CLKMBIST JTAG Controller MBIST TDO Addr. Read Back Port 1 Readback Register MRST A0P1 - A15P1(1) CNTRDP1 MKRDP1 MKLDP1 CNTINCP1 CNTLDP1 CNTRSTP1 CLKP1 MRST CNTINT P1 Port 1 Mask Register Priority Decision Logic Port 1 Counter/ Address Register Port 1 Address Decode 64KX18 Memory Array , R/WP1 CE0P1 CE1P1 CLK P1 Port 1 Interrupt Logic INTP1 MRST NOTE: 1. A15x is a NC for IDT70V5378. 2. Port 2, Port 3, and Port 4 Logic Blocks are similar to Port 1 Logic Blocks. 5649 drw 01 AUGUST 2003 DSC-5649/3 1 ©2003 Integrated Device Technology, Inc. IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges The IDT70V5388/78 is a high-speed 64/32Kx18 bit synchronous FourPort RAM. The memory array utilizes FourPort memory cells to allow simultaneous access of any address from all four ports. Registers on control, data, and address inputs provide minimal setup and hold times. The timing latitude provided by this approach allows systems to be designed with very short cycle times. With an input data register and integrated burst counters, the 70V5388/78 has been optimized for applications having unidirectional or bi-directional data flow in bursts. An automatic power down feature, controlled by CE0 and CE1, permits the on-chip circuitry of each port to enter a very low standby power mode. The IDT70V5388/78 provides a wide range of func- Description tions specially designed to facilitate system operations. These include full-boundary, maskable address counters with associated interrupts for each port, mailbox interrupt flags on each port to facilitate inter-port communications, Memory Built-In Self-Test (MBIST), JTAG support and an asynchronous Master Reset to simplify device initialization. In addition, the address lines have been set up as I/O pins, to permit the support of CNTRD (the ability to output the current value of the internal address counter on the address lines) and MKRD (the ability to output the current value of the counter mask register). For specific details on the device operation, please refer to the Functional Description and subsequent explanatory sections, beginning on page 21. 2 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Pin Configuration(4) 70V5388/78BG BG-272(2) 272-Pin BGA Top View(3) 09/25/02 1 A B C D E F G H J K L M N P R T U V W . LB P1 VDD A14 P1 VSS A10 P1 A7 P1 VSS A3 P1 VDD A0 P1 A0 P2 VDD A3 P2 VSS A7 P2 A10 P2 VSS A14 P2 VDD LB P2 2 I/O17 P2 UB P1 A15(1) P1 A12 P1 A11 P1 A8 P1 A5 P1 A4 P1 A1 P1 INT P1 INT P2 A1 P2 A4 P2 A5 P2 A8 P2 A11 P2 A12 P2 A15(1) P2 UB P2 I/O8 P1 3 I/O15 P2 I/O16 P2 CE1 P1 A13 P1 4 I/O13 P2 I/O14 P2 CE0 P1 OE P1 5 I/O11 P2 I/O12 P2 R/W P1 VDD 6 I/O9 P2 I/O10 P2 I/O15 P1 VSS 7 I/O16 P1 I/O17 P1 VSS 8 I/O14 P1 I/O13 P1 VSS 9 I/O12 P1 I/O11 P1 I/O9 P1 VDD 10 11 12 I/O10 P1 TMS I/O10 P4 TDI I/O12 P4 I/O11 P4 I/O9 P4 VDD 13 14 15 16 17 18 19 20 I/O14 P4 I/O13 P4 V SS I/O16 P4 I/O17 P4 VSS I/O9 P3 I/O10 P3 I/O15 P4 VSS I/O11 P3 I/O12 P3 R/W P4 VDD I/O13 P3 I/O14 P3 CE0 P4 OE P4 I/O15 P3 I/O16 P3 CE1 P4 A13 P4 I/O17 P3 UB P4 A15(1) P4 A12 P4 A11 P4 A8 P4 A5 P4 A4 P4 A1 P4 LB P4 VDD A14 P4 VSS A B C D E F G H J K L M N P R T U V W Y , TCK TDO VSS VDD VSS VSS VDD VSS MKRD CNTRD P1 P1 A9 P1 A6 P1 CNTINT P1 CNTINC P1 CNTRD MKRD P4 P4 CNTINT P4 CNTINC P4 A10 P4 A7 P4 VSS A3 P4 VDD A0 P4 A0 P3 VDD A3 P3 VSS A7 P3 A10 P3 VSS A14 P3 A9 P4 A6 P4 MKLD CNTLD P1 P1 A2 P1 CNTRST P1 CNTLD MKLD P4 P4 GND (5) VDD CLK P1 GND (5) GND (5) GND(5) VDD A2 P4 GND (5) GND(5) GND(5) GND(5) CLK CNTRST INT P4 P4 P4 VSS CLK P3 CNTRST INT P3 P3 CNTRST VSS P2 GND (5) GND (5) GND (5) GND (5) A2 P2 CLK P2 GND (5) GND (5) GND (5) GND (5) A2 P3 A1 P3 A4 P3 A5 P3 A8 P3 A11 P3 A12 P3 A15(1) P3 UB P3 I/O8 P4 MKLD CNTLD P2 P2 A6 P2 A9 P2 CNTINC P2 CNTINT P2 CNTLD MKLD P3 P3 CNTINC P3 CNTINT P3 A6 P3 A9 P3 MKRD CNTRD P2 P2 A13 P2 CE1 P2 I/O7 P1 I/O6 P1 OE P2 CE 0 P2 I/O5 P1 I/O4 P1 VDD R/W P2 I/O3 P1 I/O2 P1 VSS I/O6 P2 I/O1 P1 I/O0 P1 VSS VDD VDD I/O0 P2 I/O2 P2 I/O3 P2 VSS VSS VDD I/O0 P3 I/O2 P3 I/O3 P3 VDD VSS VSS I/O6 P3 I/O1 P4 I/O0 P4 VDD R/W P3 I/O3 P4 I/O2 P4 CNTRD MKRD P3 P3 OE P3 CE0 P3 I/O5 P4 I/O4 P4 A13 P3 CE1 P3 I/O7 P4 I/O6 P4 VSS I/O8 P2 I/O7 P2 VSS TRST NC VSS I/O4 P3 I/O5 P3 VSS I/O8 P3 I/O7 P3 I/O4 P2 I/O5 P2 MRST CLKMBIST VDD LB P3 Y I/O1 P2 I/O1 P3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 5649 drw 03 NOTES: 1. A15 x is a NC for IDT70V5378. 2. This package code is used to reference the package diagram. 3. This text does not indicate orientation of the actual part marking. 4. Package body is approximately 27mm x 27mm x 2.33mm, with 1.27mm ball-pitch. 5. Central balls are for thermal dissipation only. They are connected to device V SS. 3 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Pin Configuration(2) 70V5388/78BC BC-256(3) 256-Pin BGA(4) Top View 09/25/02 1 A B C D E F G H J K L M N P R T R/W P1 2 OE P1 3 LB P1 4 I/O16 P2 5 I/O13 P2 6 I/O9 P2 7 I/O14 P1 8 I/O10 P1 9 I/O9 P4 10 I/O12 P4 11 I/O16 P4 12 13 14 I/O11 P3 15 16 UB P4 I/O15 P3 I/O17 P3 CE1 P4 A B C D E F G H J K L M N P R T A15(1) P1 CE1 P1 UB P1 I/O17 P2 I/O14 I/O10 P2 P2 I/O15 P1 I/O11 P1 TDI TDO TCK I/O13 I/O17 I/O12 P4 P4 P3 I/O16 P3 LB P4 R/W P4 CE0 P4 A14 P1 A13 P1 CE0 P1 I/O15 P2 I/O12 P2 I/O17 I/O12 P1 P1 I/O9 P1 I/O11 P4 I/O15 I/O10 P4 P3 I/O14 P3 OE P4 A15(1) P4 A14 P4 A10 P1 A12 P1 A11 P1 A9 P1 I/O11 P2 I/O16 I/O13 P1 P1 TMS I/O10 P4 I/O14 P4 I/O9 P3 I/O13 P3 A11 P4 A12 P4 A13 P4 A7 P1 A8 P1 A6 P1 A5 P1 VDD VDD VDD VDD VDD VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDD VDD VDD VSS VSS VDD VSS P4 A6 P4 A7 P4 A8 P4 A10 P4 A9 P4 A3 P1 A4 P1 A2 P1 A1 P1 VDD VDD VDD VSS INT P1 A1 P4 A2 P4 A3 P4 A5 P4 A4 P4 CLK P1 A0 P1 CNTRD CNTINC P1 P1 CNTLD CNTINC CNTRD P4 P4 P4 A0 P4 CLK P4 VSS CLK P2 CNTLD CNTRST CNTINT P1 P1 P1 MKLD P1 CNTRST MKRD P4 INT CNTINT MKLD P4 P4 P4 VSS CLK P3 CNTRST INT P2 P2 CNTINT MKRD P2 P1 VSS VSS VDD VDD I/O6 P2 VSS VSS VSS VSS CNTRST P3 INT CNTINT MKLD P3 P3 P3 CNTRD MKRD CNTINC CNTLD MKLD P2 P2 P2 P2 P2 VSS VSS VSS CNTLD CNTINC MKRD P3 P3 P3 A0 P3 CNTRD P3 A3 P2 A4 P2 A2 P2 A1 P2 A0 P2 VDD VSS VDD I/O2 P2 VSS VDD VDD I/O7 P3 VDD VDD I/O2 P4 A1 P3 A3 P3 A4 P3 A2 P3 A8 P2 A9 P2 A7 P2 A6 P2 A5 P2 VDD VDD VDD TRST MRST CLKMBIST A5 P3 A7 P3 A8 P3 A6 P3 A11 P2 A12 P2 A10 P2 I/O5 P1 I/O1 P1 I/O3 P3 A9 P3 A11 P3 A12 P3 A10 P3 A13 P2 A14 P2 R/W P2 I/O7 P1 I/O2 P1 I/O7 P2 I/O3 P2 I/O0 P3 I/O4 P3 I/O8 P3 I/O3 P4 I/O6 P4 CE0 P3 A14 P3 A13 P3 A15(1) P2 CE1 P2 UB P2 I/O8 P1 I/O4 P1 I/O0 P1 I/O5 P2 I/O1 P2 I/O2 P3 I/O6 P3 I/O1 P4 I/O5 P4 I/O7 P4 UB P3 CE1 P3 A15(1) P3 CE0 P2 OE P2 LB P2 I/O6 P1 I/O3 P1 I/O8 P2 I/O4 P2 I/O0 P2 I/O1 P3 I/O5 P3 I/O0 P4 I/O4 P4 I/O8 P4 LB P3 OE P3 R/W P3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 5649 drw 04 NOTES: 1. A15x is a NC for IDT70V5378. 2. Package body is approximately 17mm x 17mm x 1.4mm, with 1.0mm ball-pitch. 3. This package code is used to reference the package diagram. 4. This text does not indicate orientation of the actual part-marking. 4 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Pin Definitions Port 1 A0P1 - A15P1(1) I/O0P1 - I/O17P1 CLKP1 Port 2 A0P2 - A15P2(1) I/O0P2 - I/O17P2 CLKP2 Port 3 A0P3 - A15P3(1) I/O0P3 - I/017P3 CLKP3 Port 4 A0P4 - A15P4(1) I/O0P4 - I/O17P4 CLKP4 Description Address Inputs. In the CNTRD and MKRD o perations, these pins serve as outputs for the internal address counter and the internal counter mask register respectively. Data Bus Input/Output. Clock Input. The maximum clock input rate is fMAX. The clock signal can be free running or strobed depending on system requirements. Master Reset Input. MRST is an asycnchronous input, and affects all ports. It must be asserted LOW (MRST = VIL) at initial power-up. Master Reset sets the internal value of all address counters to zero, and sets the counter mask registers for each port to 'unmasked'. It also resets the output flags for the mailboxes and the counter interrupts ( INT = CNTINT = VIH) and deselects all registered control signals. CE0P2, CE1P2 CE0P3, CE1P3 CE0P4, CE1P4 Chip Enable Inputs. To activate any port, both signals must be asserted to their active states (CE0 = VIL, CE1 = VIH). A g iven port is disabled if either chip enable is deasserted (CE0 = VIH and/or CE1 = VIL). Read/Write Enable Input. This signal is asserted LOW (R/ W = VIL) in order to write to the FourPort memory array, and it is asserted HIGH (R/W = VIH) in order to read from the array. Lower Byte Select Input (I/O0 - I/O8). Asserting this signal LOW ( LB = VIL) enables read/write o perations to the lower byte. For read operations, this signal is used in conjunction with OE in order to drive output data on the lower byte of the data bus. Upper Byte Select Input (I/O9 - I/O17). A sserting this signal LOW (LB = VIL) e nables read/write o perations to the upper byte. For read operations, this signal is used in conjunction with OE in order to drive output data on the upper byte of the data bus. Output Enable Input. Asserting this signal LOW ( OE = VIL) enables the device to drive data on the I/O pins during read operation. OE is an asychronous input. Counter Load Input. Asserting this signal LOW ( CNTLD = VIL) loads the address on the address lines (A 0 - A15(1)) into the internal address counter for that port. Counter Increment Input. Asserting this signal LOW ( CNTINC = VIL) increments the internal address counter for that port on each rising edge of the clock signal. The counter will increment as defined by the counter mask register for that port (default mode is to advance one address on each clock cycle). Counter Readback Input. When asserted LOW (CNTRD = VIL) causes that port to output the value of its internal address counter on the address lines for that port. Counter readback is independent of the chip enables for that port. If the port is activated (CE0 = VIL and CE1 = VIH), d uring the counter readback operation, then the data bus will output the data associated with that readback address in the FourPort memory array (assuming that the byte enables and output enables are also asserted). Truth Table III indicates the required states for all other counter controls during this operation. The specific operation and timing of this funcion is described in detail in the text. Counter Reset Input. Asserting this signal LOW (CNTRST = VIL) resets the address counter for that port to zero. Counter Interrupt Flag Output. This signal is asserted LOW (CNTINT = VIL) when the internal address counter for that port 'wraps around' from max address [(the counter will increment as defined by the counter mask register for that port (default mode is to advance one address on each clock cycle)] to address min. as the result of counter increment ( CNTINT = V IL). The signal goes LOW for one clock cycle, then automatically resets. 5649 tbl 01 MRST CE0P1, CE1P1 R/WPI R/WP2 R/WP3 R/WP4 LBP1 LBP2 LBP3 LBP4 UBP1 UBP2 UBP3 UBP4 OEP1 OEP2 OEP3 OEP4 CNTLDP1 CNTLDP2 CNTLDP3 CNTLDP4 CNTINCP1 CNTINCP2 CNTINCP3 CNTINCP4 CNTRDP1 CNTRDP2 CNTRDP3 CNTRDP4 CNTRSTP1 CNTRSTP2 CNTRSTP3 CNTRSTP4 CNTINTP1 CNTINTP2 CNTINTP3 CNTINTP4 5 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Pin Definitions (con't.) Port 1 MKLDP1 Port 2 MKLDP2 Port 3 MKLDP3 Port 4 MKLDP4 Description Counter Mask Register Load Input. Asserting this signal LOW (MKLD = VIL) loads the address on the address lines (A0 - A15(1)) into the counter mask register for that port. Counter mask register operations are described in detail in the text. Counter Mask Register Readback Input. Asserting this signal LOW (MKRD = VIL) causes that port to output the value of its internal counter mask register on the address lines (A0 - A15(1)) for that port. Address Counter and Counter-Mask Operational Table indicates the required states for all other counter controls during this operation. Counter mask register readback is independent of the chip enables for that port. If the port is activated (CE0 = VIL and CE1 = VIH) during the counter mask register readback operation, then the data bus will output the data associated with that address in the FourPort memory array ( assuming that the byte enables and output enables are also asserted). The specific operation and timing of this function is described in detail in the text . Interrupt Flag Output. The FourPort is equipped with mailbox functions: each port has a specific address wthin the memory array which, when written by any of the other ports, will generate an interrupt flag to that port. The port clears its interrupt by reading that address. The memory location is a valid address for data storage: a full 18-bit word can be stored for recall by the target port or any other port. The mailbox functions and associated interrupts are described in detail in the text. JTAG Input: Test Mode Select JTAG Input: Test Mode Reset (Intialize TAP Controller and reset the MBIST Controller) JTAG Input: Test Clock JTAG Input: Test Data Input (serial) JTAG Output: Test Data Output (serial) MBIST Input: MBIST Clock Thermal Grounds (should be treated like V SS) Core Power Supply (3.3V) Electrical Grounds (0V) 5649 tbl 02 MKRDP1 MKRDP2 MKRDP3 MKRDP4 INTP1 INTP2 INTP3 INTP4 TMS TRST TCK TDI TDO CLKMBIST GND VDD VSS NOTE: 1. A15x is a NC for IDT70V5378. 6 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Truth Table I—Read/Write and Enable Control(1,2,3) OE X X X X X X L L L H CLK ↑ ↑ ↑ ↑ ↑ ↑ ↑ ↑ ↑ ↑ CE0 H X L L L L L L L X CE 1 X L H H H H H H H X UB X X H H L L H L L X LB X X H L H L L H L X R/ W X X X L L L H H H X Upper Byte I/O9-17 High-Z High-Z High-Z High-Z DIN DIN High-Z DOUT DOUT High-Z Lower Byte I/O0-8 High-Z High-Z High-Z DIN High-Z DIN DOUT High-Z DOUT High-Z MODE Deselected–Power Down Deselected–Power Down All Bytes Deselected Write to Lower Byte Only Write to Upper Byte Only Write to Both Bytes Read Lower Byte Only Read Upper Byte Only Read Both Bytes Outputs Disabled 5649 tbl 03 NOTES: 1. "H" = V IH, "L" = VIL, "X" = Don't Care. 2. CNTLD, CNTINC, CNTRST = VIH. 3. OE is an asynchronous input signal. Truth Table II—Address Counter & Mask Control(1,2) External Address X An An An X Previous Internal Address X Ap X Ap Ap Internal Address Used 0 Ap An Ap Ap + 1(5) CLK ↑ ↑ ↑ ↑ ↑ CNTLD CNTINC X X L (3) CNTRST L(3) H H H H MKLD X L H H H I/O DI/O(0) DI/O(p) DI/O (n) DI/O(p) Counter Reset to Address 0 Counter disabled (Ap reused) External Address Used MODE X X X H L(4) H H External Address Blocked—Counter disabled (Ap reused) DI/O(p+1)(5) Counter Enabled—Internal Address generation 5649 tbl 04 NOTES: 1. "H" = VIH, "L" = VIL, "X" = Don't Care. 2. Read and write operations are controlled by the appropriate setting of R/W, CE0, CE 1, LB, UB and OE. 3. CNTLD and CNTRST are independent of all other memory control signals including CE 0, CE1 and LB, UB. 4. The address counter advances if CNTINC = VIL on the rising edge of CLK, regardless of all other memory control signals including CE0, CE1, LB, UB . 5. The counter will increment as defined by the counter mask register for that port (default mode is to advance one address on each clock cycle). 7 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Address Counter and Counter-Mask Control Operational Table (Any Port)(1,2) CLK X ↑ ↑ ↑ ↑ ↑ ↑ ↑ MRST L H H H H H H H CNTRST X L H H H X X H MKLD X X L H H X X H(3) CNTLD X X X L H X X H CNTINC X X X X L X X H CNTRD X X X X X L H X MKRD X X X X X X L X Mode MasterReset Reset Load Load Operation Counter/Address Register Reset and Mask Register Set (resets chip as per reset state definition) Counter/Address Register Reset Load of Address Lines into Mask Register Load of Address Lines into Counter/Address Register Increment Counter Increment Readback Readback Hold Readback Counter on Address Lines Readback Mask Register on Address Lines Counter Hold 5649 tbl 05 NOTES: 1. "X" = "don't care", "H" = VIH, "L" = VIL. 2. Counter operation and mask register operation is independent of Chip Enable. 3. MKLD = VIL will also hold the counter. Please refer to Truth Table II. Recommended Operating Temperature and Supply Voltage(1) Grade Commercial Industrial Ambient Temperature 0OC to +70OC -40OC to +85OC GND 0V 0V VDD 3.3V + 150mV 3.3V + 150mV 5649 tbl 06 Recommended DC Operating Conditions Symbol VDD VSS V IH VIL Parameter Supply Voltage Ground Input High Voltage (Address, Control & I/O Inputs) Input Low Voltage Min. 3.15 0 2.0 -0.3(1) Typ. 3.3 0 ____ Max. 3.45 0 VDD + 150mV 0.8 (2) Unit V V V V 5649 tbl 07 NOTES: 1. This is the parameter TA. This is the "instant on" case temperature. ____ NOTES: 1. Undershoot of VIL > -1.5V for pulse width less than 10ns is allowed. 2. VTERM must not exceed VDD + 150mV. 8 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Absolute Maximum Ratings(1) Symbol VTERM(2) TBIAS(3) TSTG TJN IOUT Rating Terminal Voltage with Respect to GND Temperature Under Bias Storage Temperature Junction Temperature DC Output Current Commercial & Industrial -0.5 to +4.6 -55 to +125 -65 to +150 +150 50 Unit V o Capacitance(1) Symbol CIN COUT(3) (TA = +25°C, F = 1.0MHZ) Parameter Input Capacitance Output Capacitance Conditions(2) VIN = 3dV VOUT = 3dV Max. 8 10.5 Unit pF pF C C C o o mA 5623 tbl 06 NOTES: 1. These parameters are determined by device characterization, but are not production tested. 2. 3dV references the interpolated capacitance when the input and output switch from 0V to 3V or from 3V to 0V. 3. COUT also references CI/O. 5649 tbl 09 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. VTERM must not exceed VDD + 150mV for more than 25% of the cycle time or 4ns maximum, and is limited to < 20mA for the period of VTERM > VDD + 150mV. 3. Ambient Temperature under DC Bias. No AC conditions. Chip Deselected. DC Electrical Characteristics Over the Operating Temperature and Supply Voltage Range (VDD = 3.3V ± 150mV) 70V5388/78S Symbol |ILI| |ILI| |ILO | VOL VOH Parameter Input Leakage Current (1) (1,2) Test Conditions VDD = Max., VIN = 0V to VDD VDD = Max., VIN = 0V to VDD VOUT = 0V to V DD, Outputs in tri-state mode IOL = + 4mA, VDD = Min. IOH = -4mA, VDD = Min. Min. ___ ___ ___ ___ Max. 10 30 10 0.4 ___ Unit µA µA µA V V 5649 tbl 10 JTAG Input Leakage Current Output Leakage Current Output Low Voltage Output High Voltage (1) 2.4 NOTE: 1. At VDD < 2.0V leakages are undefined. 2. Applicable only for TMS, TDI and TRST inputs. 9 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges DC Electrical Characteristics Over the Operating Temperature and Supply Voltage Range(3) (VDD = 3.3V ± 150mV) 70V5388/78S200 70V5388/78S166 70V5388/78S133 70V5388/78S100 Com'l Only Com'l Com'l Com'l & Ind & Ind & Ind Symbol IDD Parameter Dynamic Operating Current (All Ports Active) Standby Current (All Ports - TTL Level Inputs) Standby Current (One Port - TTL Level Inputs) Test Condition CE1 = CE2 = CE3 = CE4(5) = VIL, Outputs Disabled, f = fMAX(1) CE1 = CE2 = CE3 = CE4(5) = VIH, Outputs Disabled, f = fMAX(1) CEA = VIL and CEB = CEC = CED = VIH(5) Active Port, Outputs Disabled, f=fMAX(1) Version COM'L IND COM'L IND COM'L IND COM'L IND COM'L IND S S S S S S S S S S Typ.(4) 405 ___ Max. 470 ___ Typ.(4) 340 340 160 160 210 210 1.5 1.5 210 210 Max. 395 400 190 195 240 245 15 15 240 245 Typ.(4) 275 275 130 130 170 170 1.5 1.5 170 170 Max. 320 325 155 160 195 200 15 15 195 200 Typ.(4) 205 205 100 100 130 130 1.5 1.5 130 130 Max. 240 245 120 125 150 155 15 15 150 155 Unit mA ISB1 195 ___ 225 ___ mA ISB2 250 ___ 290 ___ mA ISB3 Full Standby Current (All All Ports Outputs Disabled, Ports - CMOS CE(5) > VDD - 0.2V, VIN > VDD - 0.2V Level Inputs) or VIN < 0.2V, f = 0(2) Full Standby Current (One Port - CMOS Level Inputs) CEA < 0.2V and CEB = CEC = CED > VDD - 0.2V(5) VIN > VDD - 0.2V or VIN < 0.2V Active Port, Outputs Disabled, f = fMAX(1) 1.5 ___ 15 ___ mA ISB4 250 ___ 290 ___ mA 5649 tbl 11 NOTES: 1. At f = fMAX, address and control lines (except Output Enable) are cycling at the maximum frequency clock cycle of 1/tCYC, using "AC TEST CONDITIONS" at input levels of GND to 3V. 2. f = 0 means no address, clock, or control lines change. Applies only to input at CMOS level standby. 3. Parameters are identical for all ports. 4. VDD = 3.3V, TA = 25°C for Typ, and are not production tested. IDD DC(f=0) = 120mA (Typ). 5. CEX = VIL means CE0X = VIL and CE1X = VIH CEX = VIH means CE0X = VIH or CE1X = V IL CEX < 0.2V means CE0X < 0.2V and CE1X > VDD - 0.2V CEX > VDD - 0.2V means CE0X > VDD - 0.2V or CE1X - 0.2V "X" represents indicator for appropriate port. 10 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges AC Test Conditions (VDDQ - 3.3V) Input Pulse Levels (Address & Controls) Input Pulse Levels (I/Os) Input Rise/Fall Times Input Timing Reference Levels Output Reference Levels Output Load GND to 3.0V GND to 3.0V 2ns 1.5V 1.5V Figure 1 5649 tbl 12 50Ω DATAOUT 50Ω 1.5V 10pF (Tester) 5649 drw 05 , Figure 1. AC Output Test Load *(For tLZ , tHZ, tWZ, tOW) 7 6 ∆ tCD (Typical, ns) 5 4 3 2 1 0 0 20 40 60 80 100 120 140 160 ∆ Capacitance (pF) from AC Test Load 5649 drw 07 Figure 2. Typical Output Derating (Lumped Capacitive Load). 11 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges AC Electrical Characteristics Over the Operating Temperature Range (Read and Write Cycle Timing) (VDD = 3.3V ± 150mV, TA = 0°C to +70°C) 70V5388/78S200 Com'l Only Symbol fMAX2 tCYC2 tCH2 tCL2 tSA tHA tSC tHC tSW tHW tSD tHD tSB tHB tSCLD tHCLD tSCINC tHCINC tSCRST tHCRST tSCRD tHCRD tSMLD tHMLD tSMRD tHMRD tOE tOLZ (1,5) tOHZ (1,5) tCD2 tCA2 tCM2 tDC tCKHZ tCKLZ (1,2,5) 70V5388/78S166 Com'l & Ind Min. ____ 70V5388/78S133 Com'l & Ind Min. ____ 70V5388/78S100 Com'l & Ind Min. ____ Parameter Maximum Frequency Clock Cycle Time Clock HIGH Time Clock LOW Time Address Setup Time Address Hold Time Chip Enable Setup Time Chip Enable Hold Time R/W Setup Time R/W Hold Time Input Data Setup Time Input Data Hold Time Byte Setup Time Byte Hold Time CNTLD Setup Time CNTLD Hold Time CNTINC Setup Time CNTINC Hold Time CNTRST Setup Time CNTRST Hold Time CNTRD Setup Time CNTRD Hold Time MKLD Setup Time MKLD Hold Time MKRD Setup Time MKRD Hold Time Output Enable to Data Valid OE to LOW-Z OE to HIGH-Z Clock to Data Valid Clock to Counter Address Readback Valid Clock to Mask Register Readback Valid Data Output Hold After Clock HIGH Clock HIGH to Output HIGH-Z Clock HIGH to Output LOW-Z Min. ____ Max. 200 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ Max. 166 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ Max. 133 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ Max. 100 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ Unit MHz ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 5 2.0 2.0 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 1.5 0.5 ____ 6 2.1 2.1 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 1.7 0.5 ____ 7.5 2.6 2.6 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 1.8 0.5 ____ 10 4 4 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 2 0.7 ____ 4.0 ____ 4.0 ____ 4.2 ____ 5 ____ 1 1 ____ ____ ____ 1 1 ____ ____ ____ 1 1 ____ ____ ____ 1 1 ____ ____ ____ 3.4 3.0 3.4 3.4 ____ 3.6 3.2 3.6 3.6 ____ 4.2 3.4 4.2 4.2 ____ 4.5 3.6 5 5 ____ 1 1 1 1 1 1 1 1 1 1 1 1 3 ____ 3 ____ 3 ____ 3 ____ (1,2,5) 5649 tbl 13a 12 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges AC Electrical Characteristics Over the Operating Temperature Range (Read and Write Cycle Timing) (VDD = 3.3V ± 150mV, TA = 0°C to +70°C) 70V5388/78S200 Com'l Only Symbol Interrupt Timing tSINT tRINT tSCINT tRCINT Clock to INT Set Time Clock to INT Reset Time Clock to CNTINT Set Time Clock to CNTINT Reset Time ____ ____ ____ ____ 70V5388/78S166 Com'l & Ind Min. Max. 70V5388/78S133 Com'l & Ind Min. Max. 70V5388/78S100 Com'l & Ind Min. Max. Unit Parameter Min. Max. 5 5 5 5 ____ ____ ____ ____ 6 6 6 6 ____ ____ ____ ____ 7.5 7.5 7.5 7.5 ____ ____ ____ ____ 10 10 10 10 ns ns ns ns Master Reset Timing tRS tRSR tROF Master Reset Pulse Width Master Reset Recovery Time Master Reset to Output Flags Reset Time 7.5 7.5 ____ ____ ____ 7.5 7.5 ____ ____ ____ 7.5 7.5 ____ ____ ____ 10 10 ____ ____ ____ ns ns ns 6.5 6.5 6.5 8 Port to Port Delays tCCS (3) JTAG Timing(4) fJTAG tTCYC tTH tTL tJS tJH tJCD tJDC fBIST tBH tBL tJRST tJRSR Maximum JTAG TAP Controller Frequency TCK Clock Cycle Time TCK Clock High Time TCK Clock Low Time JTAG Setup JTAG Hold TCK Clock Low to TDO Valid (JTAG Data Output) TCK Clock Low to TDO Invalid (JTAG Data Output Hold) Maximum CLKMBIST Frequency CLKMBIST High Time CLKMBIST Low Time JTAG Reset JTAG Reset Recovery ____ Clock-to-Clock Setup Time 4.5 ____ 5 ____ 6.5 ____ 9 ____ ns 10 ____ ____ 10 ____ ____ 10 ____ ____ 10 ____ MHz ns ns ns ns ns ns ns MHz ns ns ns ns 100 40 40 20 20 ____ 100 40 40 20 20 ____ 100 40 40 20 20 ____ 100 40 40 20 20 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ 20 ____ 20 ____ 20 ____ 20 ____ 0 ____ 0 ____ 0 ____ 0 ____ 200 ____ 166 ____ 133 ____ 100 ____ 2 2 50 50 2.5 2.5 50 50 3 3 50 50 4 4 50 50 ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ ____ 5649 tbl 13b NOTES: 1. Guaranteed by design (not production tested). 2. Valid for both data and address outputs. 3. This parameter defines the time necessary for one port to complete a write and have valid data available at that address for access from the other port(s). Attempting to read data before t CCS has elapsed will result in the output of indeterminate data. 4. JTAG operations occur at one speed (10MHz). The base device may run at any speed specified in this datasheet. 5. Transition is measured 0mV from Low or High-impedance voltage with the Output Test Load (Figure 1). 13 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Switching Waveforms Timing Waveform of Read Cycle(2) tCYC2 tCH2 CLK CE0 tCL2 tSC CE1 tSB LB, UB tHC tSC (3) tHC tHB tSB (5) tHB R/W tSW tSA tHW tHA An + 1 (1 Latency) tCD2 Qn tCKLZ (1) ADDRESS (4) An An + 2 tDC Qn + 1 An + 3 DATAOUT Qn + 2 tOLZ (5) tOHZ OE (1) , tOE NOTES: 1. OE is asynchronously controlled; all other inputs are synchronous to the rising clock edge. 5649 drw 08 2. CNTLD = VIL, CNTINC and CNTRST = VIH. 3. The output is disabled (High-Impedance state) by CE 0 = VIH, CE1 = V IL, LB, UB = VIH following the next rising edge of the clock. Refer to Truth Table I. 4. Addresses do not have to be accessed sequentially since CNTLD = VIL constantly loads the address on the rising edge of the CLK; numbers are for reference use only. 5. If LB, UB was HIGH, then the appropriate Byte of DATAOUT for Qn + 2 would be disabled (High-Impedance state). Timing Waveform of a Multi-Device Read(1,2) tCH2 CLK tSA ADDRESS(B1) tSC CE0(B1) tCYC2 tCL2 tHA A0 tHC tSC tCD2 tHC tCD2 Q0 tDC Q1 tDC A4 tCKLZ A5 tCKHZ tCD2 Q3 tCKHZ A6 A1 A2 A3 A4 A5 A6 DATAOUT(B1) tSA ADDRESS(B2) tHA A0 A1 A2 A3 tSC CE0(B2) tHC tSC tHC tCD2 tCKHZ Q2 tCKLZ tCKLZ 5649 drw 09 tCD2 , DATAOUT(B2) Q4 NOTES: 1. B1 Represents Device #1; B2 Represents Device #2. Each Device consists of one IDT70V5388/78 for this waveform, and are setup for depth expansion in this example. ADDRESS(B1) = ADDRESS(B2) in this situation. 2. LB, UB , OE, and CNTLD = VIL; CE 1(B1), CE1(B2) , R/W, CNTINC, and CNTRST = VIH. 14 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Port A Write to Port B Read(1,2,4) CLK"A" tSW R/W"A" tSA ADDRESS"A" tHA NO MATCH tHW MATCH tSD DATAIN"A" tHD VALID tCCS(3) CLK"B" tCD2 R/W"B" tSW tSA ADDRESS"B" tHW tHA NO MATCH MATCH DATAOUT"B" VALID tDC 5649 drw 10 NOTES: 1. CE 0, LB, UB, and CNTLD = VIL; CE1, CNTINC, CNTRST, MRST, MKLD, MKRD and CNTRD = VIH. 2. OE = VIL for Port "B", which is being read from. OE = VIH for Port "A", which is being written to. 3. If t CCS < minimum specified, then data from Port "B" read is not valid until following Port "B" clock cycle (ie, time from write to valid read on opposite port will be tCCS + 2 tCYC2 + tCD2). If tCCS > minimum, then data from Port "B" read is available on first Port "B" clock cycle (ie, time from write to valid read on opposite port will be tCCS + tCYC2 + tCD2). 4. All timing is the same for all ports. Port "A" may be any port. Port "B" is any other port on the device. Timing Waveform of Read-to-Write-to-Read (OE = VIL)(2) tCYC2 tCH2 CLK tCL2 CE0 tSC CE1 tSB LB, UB tHC tHB tSW tHW R/W tSW tHW ADDRESS (3) An tSA tHA An +1 An + 2 An + 2 tSD tHD Dn + 2 An + 3 An + 4 DATAIN (1) tCD2 Qn tCKHZ tCKLZ NOP (4) tCD2 Qn + 3 READ 5649 drw 11 , DATAOUT READ WRITE NOTES: 1. Output state (High, Low, or High-impedance) is determined by the previous cycle control signals. 2. CNTLD = VIL; CNTINC, and CNTRST, MRST, MKLD, MKRD and CNTRD = VIH. "NOP" is "No Operation". 3. Addresses do not have to be accessed sequentially since CNTLD = VIL constantly loads the address on the rising edge of the CLK; numbers are for reference use only. 4. "NOP" is "No Operation." Data in memory at the selected address may be corrupted and should be re-written to guarantee data integrity. 15 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Read-to-Write-to-Read ( OE Controlled)(2) tCH2 CLK CE0 tCYC2 tCL2 tSC CE1 tSB LB, UB tHC tHB tSW tHW R/W tSW tHW ADDRESS (3) An tSA tHA An +1 An + 2 tSD tHD An + 3 An + 4 An + 5 DATAIN (1) tCD2 Qn tOHZ (4) Dn + 2 Dn + 3 tCD2 tCKLZ Qn + 4 DATAOUT OE READ WRITE READ NOTES: 1. Output state (High, Low, or High-impedance) is determined by the previous cycle control signals. 2. CNTLD = VIL; CNTINC, CNTRST, MRST, MKLD, MKRD and CNTRD = VIH. 3. Addresses do not have to be accessed sequentially since CNTLD = VIL constantly loads the address on the rising edge of the CLK; numbers are for reference use only. 4. This timing does not meet requirements for fastest speed grade. This waveform indicates how logically it could be done if timing so allows. 5649 drw 12 , Timing Waveform of Read with Address Counter Advance(1) tCH2 CLK tSA ADDRESS tHA tCYC2 tCL2 An tSCLD tHCLD CNTLD tSCLD tHCLD CNTINC tCD2 DATAOUT Qx - 1(2) Qx tDC READ EXTERNAL ADDRESS READ WITH COUNTER Qn tSCLD tHCLD Qn + 1 Qn + 2(2) , Qn + 3 COUNTER HOLD 5649 drw 13 NOTES: 1. CE0, LB and UB = VIL; CE1, CNTRST, MRST, MKLD, MKRD and CNTRD = VIH. 2. If there is no address change via CNTLD = V IL (loading a new address) or CNTINC = VIL (advancing the address), i.e. CNTLD = VIH and CNTINC = V IH, then the data output remains constant for subsequent clocks. READ WITH COUNTER 16 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Write with Address Counter Advance(1) tCH2 CLK tSA ADDRESS An tHA tCYC2 tCL2 INTERNAL(3) ADDRESS tSCLD tHCLD CNTLD An(7) An + 1 An + 2 An + 3 An + 4 tSCINC tHCINC CNTINC tSD tHD DATAIN Dn WRITE EXTERNAL ADDRESS Dn + 1 Dn + 1 Dn + 2 Dn + 3 Dn + 4 WRITE WRITE WITH COUNTER COUNTER HOLD WRITE WITH COUNTER 5649 drw 14 Timing Waveform of Counter Reset(2) tCH2 CLK tSA tHA (4) tCYC2 tCL2 ADDRESS INTERNAL(3) ADDRESS Ax A0 tSW tHW R/W CNTLD An A1 An + 1 An + 2 An An + 1 tSCLD tHCLD CNTINC tSCRST tHCRST CNTRST tSCINC tHCINC tSD tHD D0 DATAIN (5) DATAOUT EXECUTE CNTRST (6) Q0 WRITE A0 READ A0 READ A1 READ ADDRESS n Q1 READ ADDRESS n+1 Qn 5649 drw 15 NOTES: 1. CE 0, LB, UB, and R/W = VIL; CE1 and CNTRST, MRST, MKLD, MKRD, and CNTRD = vIH. 2. CE 0, LB, UB = VIL; CE1 = VIH. 3. The "Internal Address" is equal to the "External Address" when CNTLD = VIL and equals the counter value when CNTLD = VIH. 4. Addresses do not have to be accessed sequentially since CNTLD = VIL constantly loads the address on the rising edge of the CLK; numbers are for reference use only. 5. Output state (High, Low, or High-impedance) is determined by the previous cycle control signals. 6. No dead cycle exists during CNTRST operation. A READ or WRITE cycle may be coincidental with the counter CNTRST cycle: Address 0000h will be accessed. Extra cycles are shown here simply for clarification. For more information on CNTRST function refer to Truth Table II. 7. CNTINC = V IL advances Internal Address from ‘An’ to ‘An +1’. The transition shown indicates the time required for the counter to advance. The ‘An +1’Address is written to during this cycle. 17 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Master Reset(1) tCYC2 tCH2 CLK tCL2 MRST tROF ALL ADDRESS/ DATA LINES tRS tRSR tS(2) INACTIVE ACTIVE ALL OTHER INPUTS CNTINT INT NOTES: 1. Master Reset will reset the device. For JTAG and MBIST reset please refer to the JTAG Timing specification. 2. tS is the set-up time required for all input control signals. 5649 drw 16 18 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Load and Read Address Counter(1,2,3) tCYC2 tCH2 tCL2 CLK tSA tHA An tSCLD CNTLD CNTINC tSCINC CNTRD INTERNAL ADDRESS tHCINC tSCRD tHCRD tHCLD tCKLZ tCA2 An+2(4) tCKHZ (2) (3) A0 - A15 An tCD2 An+1 tDC Qn An+2 An+2 An+2 , DATAOUT Qx-1 LOAD EXTERNAL ADDRESS Qx Qn+1 Qn+2 READ INTERNAL ADDRESS Qn+2 Qn+2 READ DATA WITH COUNTER 5649 drw 17 NOTES: 1. CE0, OE, LB and UB = VIL; CE1, R/W, CNTRST, MRST, MKLD and MKRD = VIH. 2. Address in output mode. Host must not be driving address bus after time tCKLZ in next clock cycle. 3. Address in input mode. Host can drive address bus after tCKHZ. 4. This is the value of the address counter being read out on the address lines. Timing Waveform of Load and Read Mask Register(1,2,3,4) tCYC2 tCH2 tCL2 CLK tSA A0 - A15 tSMLD MKLD tSMRD MKRD MASK INTERNAL VALUE An LOAD MASK REGISTER VALUE (1) (2) tHA An tHMLD tCKLZ tCA2 An(4) tCKHZ tHMLD An An An An An READ MASK-REGISTER VALUE 5649 drw 18 , NOTES: 1. Address in output mode. Host must not be driving address bus after time tCKLZ in next clock cycle. 2. Address in input mode. Host can drive address bus after tCKHZ. 3. CE0, OE, LB and UB = VIL; CE1, R/W, CNTRST, MRST, CNTLD, CNTRD and CNTINC = V IH. 4. This is the value of the mask register being read out on the address lines. 19 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Timing Waveform of Counter Interrupt(1,3) tCYC2 tCH2 tCL2 CLK EXTERNAL ADDRESS MKLD tSCLD CNTLD tSCINC CNTINC COUNTER INTERNAL ADDRESS (2) 007Fh xx7Dh tSMLD tHMLD tHCLD tHCINC An xx7Dh xx7Eh xx7Fh xx00h xx00h , tSCINT tRCINT 5649 drw 19 CNTINT Timing Waveform of Mailbox Interrupt Timing(4,6) tCYC2 tCH2 tCL2 CLKP1 tSA tHA PORT-1 ADDRESS INTP2 (7) FFFE (5) An tSINT An+1 tRINT An+2 An+3 tCYC2 tCH2 tCL2 CLKP2 tSA tHA PORT-2 ADDRESS Am Am+1 FFFE (5) Am+3 Am+4 , NOTES: 1. CE0, OE, LB and UB = VIL; CE1, R/W, CNTRST, MRST, CNTRD and MKRD = VIH. 2. CNTINT is always driven. 3. CNTINT goes LOW as the counter address increments (via CNTINC = VIL) past the maximum value programmed into the mask register and 'wraps around' to xx00h CNTINT stays LOW for one cycle, then resets. In this example, the mask register was programmed at xx7Fh ('x' indicates "Don't Care"). The Counter Mask Register operations are detailed on page 24. 4. CNTRST, MRST, CNTRD CNTINC , MKRD and MKLD = V IH. The mailbox interrupt circuitry relies on the state of the chip enables, the read/write signal, and the address location to generate or clear interrupts as appropriate - other control signals such as OE, LB and UB are "Don't Care". Please refer to Truth Table III (page 22) for further explanation. 5. Address FFFEh is the mailbox location for Port 2 of IDT70V5388. Refer to Truth Table III for mailbox location of other Ports (page 22). 6. Port 1 is configured for a write operation (setting the interrupt) in this example, and Port 2 is configured for a read operation (clearing the interrupt). Ports 1 and 2 are used for an example: any port can set an interrupt to any other port per the operations in Truth Table III (page 22). 7. The interrupt flag is always set with respect to the rising edge of the writing port's clock, and cleared with respect to the rising edge of the reading port's clock. 5649 drw 20 20 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Functional Description The IDT70V5388/78 provides a true synchronous FourPort Static RAM interface. Registered inputs provide minimal set-up and hold times on address, data, and all critical control inputs. All internal registers are clocked on the rising edge of the clock signal, however, the self-timed internal write pulse is independent of the LOW to HIGH transition of the clock signal and the duration of the R/W input signal. This is done in order to offer the fastest possible cycle times and highest data throughput. At 200 MHz, the device supports a cycle time of 5 ns, and provides a pipelined data output of 3.0 ns from clock edge to data valid. Four ports operating at 200 MHz, each with a bus width of 18 bits, results in a data throughput rate of nearly 14 Gbps. As a true synchronous device, the IDT70V5388/78 provides the flexibility to clock each port independently: the ports may run at different frequencies and/or out of synchronization with each other. As a true FourPort device, the IDT70V5388/78 is capable of performing simultaneous reads from all ports on the same address location. Care should be taken when attempting to write and read address locations simultaneously: the timing diagrams depict the critical parameter tCCS, which determines the amount of time needed to ensure that the write has successfully been completed and so valid data is available for output. Violation of tCCS may produce indeterminate data for the read. Two or more ports attempting to write the same address location simultaneously will result in indeterminate data recorded at that address. Each port is equipped with dual chip enables, CE0 and CE1. A HIGH on CE0 or a LOW on CE1 for one clock cycle on any port will power down the internal circuitry on that port in order to reduce static power consumption. The multiple chip enables also allow easier banking of multiple IDT70V5388/78s for depth expansion configurations. One cycle is required with chip enables reasserted to reactivate the outputs. Depth and Width Expansion The IDT70V5388/78 features dual chip enables (refer to Truth Table I) in order to facilitate rapid and simple depth expansion with no requirements for external logic. Figure 4 illustrates how to control the various chip enables in order to expand two devices in depth. The IDT70V5388/78 can also be used in applications requiring expanded width, as indicated in Figure 3. Through combining the control signals, the devices can be grouped as necessary to accommodate applications requiring 36-bits or wider. A16/A15(1) IDT70V5388/78 CE0 CE1 VDD IDT70V5388/78 CE0 CE1 VDD Control Inputs Control Inputs IDT70V5388/78 CE1 CE0 IDT70V5388/78 CE1 CE0 UB, LB R/W, OE, CLK, CNTLD, CNTRST, CNTINC 5649 drw 21 Control Inputs Control Inputs Figure 3. Depth and Width Expansion with IDT70V5388/78 NOTE: 1. A16 is for IDT70V5388, A15 is for IDT70V5378. 21 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Mailbox Interrupts The IDT70V5388/78 supports mailbox interrupts, facilitating communication among the devices attached to each port. If the user chooses the interrupt function, then each of the upper four address locations in the memory array are assigned as a mailbox for one of the ports: FFFFh (7FFFh for IDT70V5378) is the mailbox for Port 1, FFFEh (7FFEh for IDT70V5378) is the mailbox for Port 2, FFFDh (7FFDh for IDT70V5378) is the mailbox for Port 3, and FFFCh (7FFCh for IDT70V5378) is the mailbox for Port 4. Truth Table III details the operation of the mailbox interrupt functions. A given port’s interrupt is set (i.e., INT goes LOW) whenever any other port on the device writes to the given port’s address. For example, Port 1’s INT will go LOW if Port 2, Port 3, or Port 4 write to FFFFh (7FFFh for IDT70V5378). The INT will go LOW in relation to the clock on the writing port (see also the Mailbox Interrupt Timing waveform on page 20). If a port writes to its own mailbox, no interrupt is generated. The mailbox location is a valid memory address: the user can store an 18-bit data word at that location for retrieval by the target port. In the event that two or more ports attempt to set an interrupt to the same port at the same time, the interrupt signal will go LOW, but the data actually stored at that location will be indeterminate. The actual interrupt is generated as a result of evaluating the state of the address pins, the chip enables, and the R/W pin: if the user wishes to set an interrupt to a specific port without changing the data stored in that port’s mailbox, it is possible to do so by disabling the byte enables during that write cycle. Once INT has gone LOW for a specific port, that port can reset the INT by reading its assigned mailbox. In the case of Port 1, it would clear its INT signal by reading FFFFh (7FFFh for IDT70V5378). As stated previously, the interrupt operation executes based on the state of the address pins, the chip enables, and the R/W pin: it is possible to clear the interrupt by asserting a read to the appropriate location while keeping the output enable (OE) or the byte enables deasserted, and so avoid having to drive data on the I/O bus. The INT is reset, or goes HIGH again, in relation to the reading port’s clock signal. Master Reset The IDT70V5388/78 is equipped with an asynchronous Master Reset input, which can be asserted independently of all clock inputs and will take effect per the Master Reset timing waveform on page 18. The Master Reset sets the internal value of all address counters to zero, and sets the counter mask register on each port to all ones (i.e., completely unmasked). It also resets all mailbox interrupts and counter interrupts to HIGH (i.e., non-asserted) and sets all registered control signals to a deselected state. A Master Reset operation must be performed after power-up, in order to initialize the various registers on the device to a known state. Master Reset will reset the device. For JTAG and MBIST reset please refer to the JTAG Section on page 25. — Truth Table III—Mailbox Interrupt Flag Operations Port 1(1,2) R/W X H L X L X L X CE X L L X L X L X A15-A 0(4) X FFFF FFFE X FFFD X FFFC X INT L H X X X X X X R/W L X X H L X L X Port 2(1,2) CE L X X L L X L X A15-A 0(4) FFFF X X FFFE FFFD X FFFC X INT X X L H X X X X R/W L X L X X H L X Port 3(1,2) CE L X L X X L L X A15-A 0(4) FFFF X FFFE X X FFFD FFFC X INT X X X X L H X X R/W L X L X L X X H Port 4(1,2) CE L X L X L X X L A15-A 0(4) FFFF X FFFE X FFFD X X FFFC INT X X X X X X L H Function Set Port 1 INT Flag(3) Reset Port 1 INT Flag Set Port 2 INT Flag(3) Reset Port 2 INT Flag Set Port 3 INT Flag(3) Reset Port 3 INT Flag Set Port 4 INT Flag(3) Reset Port 4 INT Flag 5649 tbl 14 NOTES: 1. The status of OE is a "Don't Care" for the interrupt logic circuitry. If it is desirable to reset the interrupt flag on a given port while keeping the I/O bus in a tri-state condition, then this can be accomplished by setting OE = VIH while the read access is asserted to the appropriate address location. 2. The status of the LB and UB controls are "Don't Care" for the interrupt circuitry. If it is desirable to set the interrupt flag to a specific port without overwriting the data value already stored at the mailbox location, then this can be accomplished by setting LB = UB = VIH during the write access for that specific mailbox. Similarly, if it desirable to reset the interrupt flag on a given port while keeping the I/O bus in a tri-state condition, then this can be accomplished by setting LB = UB = V IH while the read access is asserted to the appropriate address location. 3. The interrupt to a specific port can be set by any one of the other three ports. The appropriate control states for the other three ports are depicted above. In the event that two or more ports attempt to set the same interrupt flag simultaneously via a valid data write, the data stored at the mailbox location will be indeterminate. 4. A15 is a NC for IDT70V5378, therefore Mailbox Interrupt Addresses are 7FFF, 7FFE, 7FFD and 7FFC. Address comparison will be for A0 - A14 . 22 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Address Counter Control Operations Each port on the IDT70V5388/78 is equipped with an internal address counter, to ease the process of bursting data into or out of the device. Truth Table II depicts the specific operation of the counter functions, to include the order of priority among the signals. All counter controls are independent of chip enables. The device supports the ability to load a new address value on each access, or to load an address value on a given clock cycle via the CNTLD control and then allow the counter to increase that value by preset increments on each successive clock via the CNTINC control (see also the Counter Mask Operations section that follows). The counter can be suspended on any clock cycle by disabling the CNTINC, and it can be reset to zero on any clock cycle by asserting the CNTRST control. CNTRST only affects the address value stored in the counter: it has no effect on the counter mask register. When the counter reaches the maximum value in the array (i.e., address FFFFh for IDT70V5388 and address 7FFFh for IDT70V5378) or it reaches the highest value permitted by the Counter Mask Register, it then ‘wraps around’ to the beginning of the array. When Address Min is reached via counter increment (i.e., not as a result of an external address load), then the CNTINT signal for that port is driven low for one clock cycle, automatically resetting on the next cycle. When the C NTRD c ontrol is asserted, the IDT70V5388/78 will output the current address stored in the internal counter for that port as noted in the Load and Read Address Counter timing waveform on page 19. The address will be output on the address lines. During this output, the data I/Os will be driven in accordance with the settings of the chip enables, byte enables, and the output enable on that port: the device does not automatically tri-state these pins during the address readback operation. CNTRD MKRD Read Back Register Addr. Read Back MKLD Address (I/O) Mask Register Memory Array CNTLD CNTINC CNTRST CLK Counter/ Address Register , 5649 drw 22 Figure 4. Logic Block Diagram for Read Back Operations 23 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Counter-Mask Register CNTINT STEP 1 Load Counter-Mask Register = FF H 00 A15(2)A14 0's 011111111 A8 A7 A6 A5 A4 A3 A2 A1 A0 Counter Address Masked Address STEP 2 Load Address Counter = FD H 00 A15(2) A14 0's 011111101 A8 A7 A6 A5 A4 A3 A2 A1 A0 , STEP 3 Max Address Register H XX A15(2)A14 X's X 111 11111 A8 A7 A6 A5 A4 A3 A2 A1 A0 STEP 4 Max + 1 Address Register L XX A15(2)A14 X's X 00000000 A8 A7 A6 A5 A4 A3 A2 A1 A0 5649 drw 23 Figure 5. Programmable Counter-Mask Register Operation (1) NOTE: 1. The "X's" in this diagram represent the upper bits of the counter. 2. A15 is a NC for IDT70V5378. The internal address counter on each port has an associated Counter Mask Register that allows for configuration of the internal address counter on that port. Truth Table III groups the operations of the address counter with those of the counter mask register, to include Master Reset and applicable readback operations. Each bit in the mask register controls the corresponding bit in the internal address counter: writing a “1” to a bit in the mask register allows that bit to increment in response to CNTINC, while writing a “0” to a bit masks it (i.e., locks it at whatever value is loaded via CNTLD). The mask register is extremely flexible: every bit can be controlled independently of every other bit. The counter simply concatenates those bits that have not been masked, giving the user great selectivity in determining which portions of the memory array are available to a particular port for burst operations. Figure 5 illustrates the operation of the Counter Mask Register in simply constraining a port to a selected portion of the array, specifically addresses 0000h to 00FFh. In step one, the mask register is loaded with 00FFh via MKLD (see also the Load and Read Mask Register timing waveform on page 19). In step two, a starting address of 00FD is asserted for the start point of a burst, and the CNTINC control is enabled. Step three indicates the address counter incrementing to 00FFh. In step four, the internal counter determines that all address values greater than 00FFh have been masked, and so it increments past this ‘max’ value to 0000h. As a result of reaching 0000h via the CNTINC operation, the CNTINT output for this port is automatically triggered – it will go low for one clock cycle and then reset. The example depicted in Figure 5 is a very simple one: it is also possible to mask non-contiguous bits, such as loading 5555h in the mask register. As stated previously, the address counter simply concatenates all bits that have not been masked and continues to increment those bits in accordance with the CNTINC control: in this fashion, if the mask register is set at 5555h and a start address of 0007h is asserted via CNTLD, the next value the counter will increment to in response to the CNTINC control is 0012h, then 0013h, then 0016h, etc. Besides supporting precise control of which portions of the array are available to a particular port in burst operations, the independent control on the mask register bits also provides excellent flexibility in determining the value by which the counter will increment. For example, setting bit 0 of the mask register to “0” masks it from counter operation, effectively configuring that port to count by increments of two. This can be very useful in configuring two ports to work in combination, effectively creating a single 36-bit port. Thus, Port 1 can be configured to count by two starting on even addresses (the start point is asserted via CNTLD), and Port 2 can be configured to count by two starting on odd addresses (again via CNTLD). The two ports together will operate on 36-bit data words, storing half of each word in an even-numbered address, the other half in an odd-numbered address. Setting bits 1 and 0 of the mask register on a given port to “0” configures that port to count 24 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges in increments of four: masking bits 2, 1, and 0 configures that port to count in increments of eight, and so on. The ability to set the increments by which the counters will advance gives the user the ability to interleave memory operations among the ports, minimizing the concerns that a given address might be written by more than one port at any given point in time (an operation that would have indeterminate results). JTAG Support The IDT70V5388/78 provides a serial boundary scan test access port . The JTAG tables starting on page 29 provide the specific details for the JTAG implementation on this device. The IDT70V5388/78 executes a JTAG test logic reset upon power-up. This power-up reset will initialize the TAP controller and MBIST controller. In most power environments no further action is required. However, if the user has any concern about the system’s voltage states during power-up, then the user can use the optional TRST input as part of a board’s power on reset sequence. The TRST pin also provides an alternate means of resetting the JTAG test logic when required, and is available for use by external JTAG controllers as an asynchronous reset signal. If the user does not plan to rely on the optional TRST pin, but wants to use JTAG functionality, the TRST pin should either be tied HIGH (preferred implementation) or left floating. If JTAG operations are not desired, the user has a number of options for disabling the JTAG functions. One would be to simply tie TCK LOW, leaving all other JTAG pins floating (alternatively, TDI and TMS could be tied HIGH). Since the device executes a JTAG reset upon power-up: with TCK tied LOW, no further clocking of the TAP will occur and no JTAG operations will take place. Alternatively, the user can opt to tie TRST LOW (either in lieu of or in addition to tying TCK LOW) and the TAP will be locked in a reset condition, blocking all JTAG operations. while a "1" indicates that the memory array passed. The rest of the MRR contains the total number of failed read cycles in the entire MBIST sequence. The IDT70V5388/78 MBIST function has been supplemented with the ability for the user to force a failure report from the device. This allows the user the flexibility of validating the MBIST function itself, by verifying that the device is able to report faults as well as passing results. The two modes of operation, normal MBIST testing and forced error reporting, are controlled via the JTAG TAP interface using the instruction PROGRAM_MBIST_MODE_SELECT. For further detail, please refer to the System Interface Parameters table on page 28. The MBIST function executes once the RUNBIST instruction is input via the JTAG interface. The entire MBIST test will be performed with a deterministic number of TCK cycles depending on the TCK and CLKMBIST frequency. This can be calculated by using the following formula: tCYC = tCYC[CLKMBIST] tCYC[TCK] x m + SPC, where: tCYC is the total number of TCK cycles required to run MBIST. SPC is the synchronization padding cycles (typically 4-6 cycles, to accommodate state machine overhead, turnaround cycles, etc.) m is a constant that represents the number of read and write operations required to run the internal MBIST algorithms (14,811,136) for both IDT70V5388 and IDT70V5378. Memory Built-In-Test Operations Go-NoGo Testing The IDT70V5388/78 is equipped with a self-test function that can be run by the user as the result of a single instruction, implemented via the JTAG TAP interface. If multiple FourPort devices are used on the same board, all can execute MBIST simultaneously, facilitating board checkout. The MBIST function executes a Go-NoGo test within the device, which then captures pass-fail information and failure count in a special register called the MBIST Result Register (MRR). Upon completion of the test, the MRR can be scanned out via the JTAG interface, using the internal scan operation. Bit zero of the MRR (MRR[0]) is a don't care. Bit one of the MRR (MRR[1])indicates the pass/ fail status: a "0" indicates some sort of failure was noted, 25 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges JTAG/BIST TAP Controller Block Diagram 0 Bypass Register (BYR) 1 32 0 MBIST Mode Select Register (MSR) 10 1X Selection Circuitry TDO Instruction Register (IR) TDI 25 24 MBIST Result Register (MRR) 31 30 29 0 Identification Register (IDR) 391 0 (MUX) Boundary Scan Register (BSR) CLKMBIST MBIST CONTROLLER TAP CONTROLLER TCK TMS TRST MEMORY CELL 5649 drw 25 26 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges JTAG Timing Specifications tTCYC tTL TCK tTH Device Inputs(1)/ TDI/TMS tJS Device Outputs(2)/ TDO TRST tJRST NOTES: 1. Device inputs = All device inputs except TDI, TMS, and TRST. 2. Device outputs = All device outputs except TDO. 3. To reset the test (JTAG) port without resetting the device, TMS must be held LOW for 5 cycles, or TRST must be held LOW for one cycle. tJH tJDC tJRSR tJCD 5649 drw 26 , 27 6.42 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Identification Register Definitions Instruction Field Revision Number (31:28) IDT Device ID (27:12) IDT JEDEC ID (11:1) ID Register Indicator Bit (Bit 0) NOTE: 1. Device ID for IDT70V5378 is 0x31E. Value 0x0 0x31D (1) Description Reserved for version number Defines IDT part number Allows unique identification of device vendor as IDT Indicates the presence of an ID register 5649 tbl 15 0x33 1 Scan Register Sizes Register Name Instruction (IR) MBIST Mode Select Register (MSR) Bypass (BYR) Identification (IDR) Boundary Scan (BSR) MBIST Result (MRR) Bit Size 4 2 1 32 392 Note (3) 26 5649 tbl 16 System Interface Parameters Instruction EXTEST BYPASS IDCODE Code 0000 1111 0111 0110 0001 Description Forces contents of the boundary scan cells onto the device outputs(1). Places the boundary scan register (BSR) between TDI and TDO. Places the b ypass register (BYR) between TDI and TDO. Loads the ID register (IDR) with the vendor ID code and places the register between TDI and TDO. Places the bypass register (BYR) b etween TDI and TDO. Forces all device output drivers to a High-Z state. Places the boundary scan register (BSR) between TDI and TDO. SAMPLE allows data from device inputs(2) 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. Places the MBIST Mode Register between TDI and TDO. A value of '00' written into this register will allow MBIST to run in standard memory test mode, outputting valid results as appropriate via the MBIST Result Register. A value of '11' written into the MBIST Mode Register will force the MBIST Result Register (MRR) to report a result of 'FAIL'., with 8E0000 failed read cycles noted (i.e., the MRR content = (8E0000h, 0, x). The value of the MBIST Mode Register is no t guaranteed at power-up and is not affected b y Master reset and JTAG reset. Invokes MBIST. Internally updates MBIST result register with Go-NoGo information and number of issues. PROGRAM_MBIST_MODE_REGISTER must be run prior to executing RUNBIST in order to ensure valid results. There is no need to repeat this instructio n unless the mode of operation is changed: the MMR will re tain its programmed value until overwritten or the device is powered down. Scans out partial information. Places MBIST result register (MRR) between TDI & TDO. Uses BYR. Forces contents of the boundary scan cells onto the device outputs. Places the Bypass reg ister (BYR) between TDI & TDO. Several combinations are reserved. Do not use codes other than those identified above. Several combinations arePRIVATE (for IDT internal use). Do not use codes other than those identified above. 5649 tbl 17 HIGHZ SAMPLE/PRELOAD MBIST_MODE_SELECT 1010 RUNBIST 1000 INT_SCAN CLAMP RESERVED PRIVATE 0100 0101 0010, 0011 1001, 1011, 1100, 1101, 1110 NOTES: 1. Device outputs = All device outputs except TDO. 2. Device inputs = All device inputs except TDI, TMS, and TRST . 3. The Boundary Scan Descriptive Language (BSDL) file for this device is available on the IDT website (www.idt.com), or by contacting your local IDT sales representative. 28 IDT70V5388/78 3.3V 64/32K x 18 Synchronous FourPort™ Static RAM Industrial and Commercial Temperature Ranges Ordering Information IDT XXXXX Device Type A Power 999 Speed A Package A Process/ Temperature Range Blank I Commercial (0°C to +70°C) Industrial (-40°C to +85°C) BG BC 272-ball BGA (BG272-1) 256-ball BGA (BG256-1) 200 166 133 100 Commercial Only Commercial & Industrial Commercial & Industrial Commercial & Industrial Speed in MHZ S Standard Power 70V5388 1152K (64K x 18) 3.3V FourPort™ RAM 70V5378 576K (32K x 18) 3.3V FourPort™ RAM 5649 drw 27 Datasheet Document History 08/20/02: 09/25/02: 08/20/03: Initial Public Datasheet Added 0.5M Density to Datasheet Page 10 Changed power numbers in DC Electrical Characteristics table Removed Preliminary status 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 29 6.42 for Tech Support: 831-754-4613 DualPortHelp@idt.com The IDT logo is a registered trademark of Integrated Device Technology, Inc.