43B CY7C343B 64-Macrocell MAX® EPLD Features The CY7C343B contains 64 highly flexible macrocells and 128 expander product terms. These resources are divided into four Logic Array Blocks (LABs) connected through the Programmable Inter-connect Array (PIA). There are 8 input pins, one that doubles as a clock pin when needed. The CY7C343B also has 28 I/O pins, each connected to a macrocell (6 for LABs A and C, and 8 for LABs B and D). The remaining 36 macrocells are used for embedded logic. • • • • 64 MAX macrocells in 4 LABs 8 dedicated inputs, 24 bidirectional I/O pins Programmable interconnect array Advanced 0.65-micron CMOS technology to increase performance • Available in 44-pin HLCC, PLCC • Lowest power MAX device The CY7C343B is excellent for a wide range of both synchronous and asynchronous applications. Functional Description The CY7C343B is a high-performance, high-density erasable programmable logic device, available in 44-pin PLCC and HLCC packages. Logic Block Diagram INPUT 35 9 INPUT 11 INPUT INPUT/CLK 34 12 INPUT INPUT 33 13 INPUT INPUT 31 DEDICATED INPUTS SYSTEM CLOCK LAB A I/O PINS 2 4 5 6 7 8 LAB D MACROCELL 1 MACROCELL 2 MACROCELL 3 MACROCELL 4 MACROCELL 5 MACROCELL 6 MACROCELL 56 MACROCELL 55 MACROCELL 54 MACROCELL 53 MACROCELL 52 MACROCELL 51 MACROCELL 50 MACROCELL 49 MACROCELLS 7 - 16 P I A LAB B I/O PINS 15 16 17 18 19 20 22 23 MACROCELL 17 MACROCELL 18 MACROCELL 19 MACROCELL 20 MACROCELL 21 MACROCELL 22 MACROCELL 23 MACROCELL 24 1 44 42 41 40 39 38 37 I/O PINS 30 29 28 27 26 24 I/O PINS MACROCELLS57 - 64 LAB C MACROCELL 38 MACROCELL 37 MACROCELL 36 MACROCELL 35 MACROCELL 34 MACROCELL 33 MACROCELLS39 - 48 MACROCELLS 25 - 32 (3, 14, 25, 36) (10, 21, 32, 43) VCC GND C343B-1 MAX is a registered trademark of Altera Corporation. Cypress Semiconductor Corporation Document #: 38-03038 Rev. ** • 3901 North First Street • San Jose • CA 95134 • 408-943-2600 Revised December 8, 1999 CY7C343B Pin Configuration I/O I/O 1 2 I/O 3 I/O 4 GND I/O 5 I/O I/O 6 V CC I/O I/O HLCC, PLCC Top View 44 43 42 41 40 I/O 7 39 I/O I/O 8 38 I/O INPUT 9 37 I/O GND 10 36 VCC INPUT 11 35 INPUT INPUT 12 34 INPUT/CLK INPUT 13 33 INPUT VCC 14 32 GND 31 INPUT 7C343 I/O 15 I/O 16 30 I/O I/O 17 29 I/O I/O I/O I/O V CC I/O I/O I/O GND I/O I/O I/O 18 19 20 21 22 23 24 25 26 27 28 C343B-2 Selection Guide Maximum Access Time (ns) Maximum Ratings (Above which the useful life may be impaired. For user guidelines, not tested.) Storage Temperature ..................................–65°C to+135°C Ambient Temperature with Power Applied..............................................–65°C to+135°C Maximum Junction Temperature (Under Bias)................................................................. 150°C Supply Voltage to Ground Potential[1] ............. –2.0V to+7.0V 7C343B-25 7C343B-30 7C343B-35 25 30 35 DC Output Current, per Pin[1] ...................–25 mA to +25 mA DC Input Voltage[1] .........................................–2.0V to +7.0V Operating Range Range Commercial Industrial Military Ambient Temperature VCC 0°C to +70°C 5V ±5% –40°C to +85°C 5V ±10% –55°C to +125°C (Case) 5V ±10% Note: 1. Minimum DC input is –0.3V. During transactions, the inputs may undershoot to –2.0V or overshoot to 7.0V for input currents less then 100 mA and periods shorter than 20 ns. Document #: 38-03038 Rev. ** Page 2 of 12 CY7C343B Electrical Characteristics Over the Operating Range Parameter VCC Description Supply Voltage Test Conditions Min. Max. Unit Maximum VCC rise time is 10 ms 4.75(4.5) 5.25(5.5) V VOH Output HIGH Voltage IOH = –4.0 mA DC VOL Output LOW Voltage IOL = 8 mA DC[2] VIH Input HIGH Level VIL Input LOW Level IIX Input Current IOZ Output Leakage Current tR tF [2] 2.4 V 0.45 V 2.0 VCC+0.3 V –0.3 0.8 V VI = VCC or ground –10 +10 µA VO = VCC or ground –40 +40 µA Recommended Input Rise Time 100 ns Recommended Input Fall Time 100 ns Capacitance Max. Unit CIN Parameter Input Capacitance Description VIN = 0V, f = 1.0 MHz Test Conditions 10 pF COUT Output Capacitance VOUT = 0V, f = 1.0 MHz 20 pF Note: 2. The IOH parameter refers to high-level TTL output current; the IOL parameter refers to low-level TTL output current. AC Test Loads and Waveforms R1 464Ω R1 464Ω 5V 5V OUTPUT ALL INPUT PULSES OUTPUT R2 250Ω 50 pF INCLUDING JIG AND SCOPE 3.0V INCLUDING JIG AND SCOPE (a) Equivalent to: R2 250Ω 5 pF C343B-4 10% GND <6 ns 90% 90% 10% <6 ns C343B-5 (b) THÉVENIN EQUIVALENT (commercial/military) 163 Ω OUTPUT Document #: 38-03038 Rev. ** 1.75V Page 3 of 12 CY7C343B The Programmable Interconnect Array (PIA) solves interconnect limitations by routing only the signals needed by each logic array block. The inputs to the PIA are the outputs of every macrocell within the device and the I/O pin feedback of every pin on the device. Unlike masked or programmable gate arrays, which induce variable delay dependent on routing, the PIA has a fixed delay. This eliminates undesired skews among logic signals, which may cause glitches in internal or external logic. The fixed delay, regardless of programmable interconnect array configuration, simplifies design by ensuring that internal signal skews or races are avoided. The result is simpler design implementation, often in a single pass, without the multiple internal logic placement and routing iterations required for a programmable gate array to achieve design timing objectives. Typical ICC vs. fMAX 200 ICC ACTIVE (mA) Typ. Programmable Interconnect Array 150 VCC = 5.0V Room Temp. 100 50 0 100 Hz Design Recommendations 1 kHz 10 kHz 100 kHz 1 MHz 10 MHz MAXIMUM FREQUENCY For proper operation, input and output pins must be constrained to the range GND < (VIN or VOUT) < VCC. Unused inputs must always be tied to an appropriate logic level (either VCC or GND). Each set of VCC and GND pins must be connected together directly at the device. Power supply decoupling capacitors of at least 0.2 µF must be connected between VCC and GND. For the most effective decoupling, each VCC pin should be separately decoupled to GND, directly at the device. Decoupling capacitors should have good frequency response, such as monolithic ceramic types. Timing Considerations Unless otherwise stated, propagation delays do not include expanders. When using expanders, add the maximum expander delay tEXP to the overall delay. Similarly, there is an additional tPIA delay for an input from an I/O pin when compared to a signal from a straight input pin. When calculating synchronous frequencies, use tS1 if all inputs are on the input pins. When expander logic is used in the data path, add the appropriate maximum expander delay, tEXP to tS1. Determine which of 1/(tWH + tWL), 1/tCO1, or 1/(tEXP + tS1) is the lowest frequency. The lowest of these frequencies is the maximum data path frequency for the synchronous configuration. Document #: 38-03038 Rev. ** C343B–7 Output Drive Current IO OUTPUT CURRENT (mA) TYPICAL Operation of the devices described herein with conditions above 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 data sheet is not implied. Exposure to absolute maximum ratings conditions for extended periods of time may affect device reliability. The CY7C343B contains circuitry to protect device pins from high static voltages or electric fields; however, normal precautions should be taken to avoid applying any voltage higher than maximum rated voltages. 50 MHz 250 IOL 200 VCC = 5.0V Room Temp. 150 100 IOH 50 0 1 2 3 4 VO OUTPUT VOLTAGE (V) 5 C343B–8 When calculating external asynchronous frequencies, use tAS1 if all inputs are on dedicated input pins. When expander logic is used in the data path, add the appropriate maximum expander delay, tEXP to tAS1. Determine which of 1/(tAWH + tAWL), 1/tACO1, or 1/(tEXP + tAS1) is the lowest frequency. The lowest of these frequencies is the maximum data path frequency for the asynchronous configuration. The parameter tOH indicates the system compatibility of this device when driving other synchronous logic with positive input hold times, which is controlled by the same synchronous clock. If tOH is greater than the minimum required input hold time of the subsequent synchronous logic, then the devices are guaranteed to function properly with a common synchronous clock under worst-case environmental and supply voltage conditions. Page 4 of 12 CY7C343B EXPANDER DELAY tEXP REGISTER LOGIC ARRAY CONTROL DELAY tLAC INPUT INPUT DELAY tIN LOGIC ARRAY DELAY tLAD OUTPUT DELAY tCLR tPRE tRSU tRH INPUT/ OUTPUT tOD tXZ tZX tRD tCOMB tLATCH SYSTEM CLOCK DELAY tICS PIA DELAY tPIA CLOCK DELAY tIC FEEDBACK DELAY tFD I/O DELAY tIO C343B-9 Figure 1. CY7C343B Internal Timing Model External Synchronous Switching Characteristics Over Operating Range 7C343B-25 Parameter Description Min. Max. 7C343B-30 Min. Max. Min. 30 Max. Unit 35 ns 55 ns tPD1 Dedicated Input to Combinatorial Output Delay[3] Com’l/Ind tPD2 I/O Input to Combinatorial Output Delay[3] Com’l/Ind tSU Global clock setup time Com’l/ Ind tCO1 Synchronous Clock Input to Output Delay[3] Com’l/Ind tH Input Hold Time from Synchronous Clock Input Com’l/Ind 0 0 0 ns tWH Synchronous Clock Input HIGH Time Com’l/Ind 8 10 12.5 ns tWL Synchronous Clock Input LOW Time Com’l/Ind 8 10 12.5 ns Com’l/Ind 62.5 50 40 MH z [4] 25 7C343B-35 40 15 45 20 14 25 16 ns 20 ns fMAX Maximum Register Toggle Frequency tCNT Minimum Global Clock Period Com’l/Ind tODH Output Data Hold Time After Clock Com’l/Ind 2 2 2 ns fCNT Maximum Internal Global Clock Frequency[5] Com’l/Ind 50 40 33.3 MH z 20 25 30 ns Notes: 3. C1 = 35 pF. 4. The fMAX values represent the highest frequency for pipeline data. 5. This parameter is measured with a 16-bit counter programmed into each LAB. Document #: 38-03038 Rev. ** Page 5 of 12 CY7C343B External Asynchronous Switching Characteristics Over Operating Range 7C343B-25 Parameter Description Min. Max. 7C343B-30 Min. Max. 7C343B-35 Min. Max. Unit 35 ns tACO1 Asynchronous Clock Input to Output Delay[3] Com’l/Ind tAS1 Dedicated Input or Feedback Set-Up Time to Asynchronous Clock Input Com’l/Ind 5 6 8 ns tAH Input Hold Time from Asynchronous Clock Input Com’l/Ind 6 8 10 ns tAWH Asynchronous Clock Input HIGH Time[6] Com’l/Ind 11 14 16 ns tAWL Asynchronous Clock Input LOW Time[6] Com’l/Ind 9 11 14 ns tACNT Minimum Internal Array Clock Frequency Com’l/Ind fACNT Maximum Internal Array Clock Frequency[5] Com’l/Ind 25 30 20 50 25 40 30 33.3 ns MHz Internal Switching Characteristics Over Operating Range 7C343B-25 Parameter Description Min. Max. 7C343B-30 Min. Max. 7C343B-35 Min. Max. Unit tIN Dedicated Input Pad and Buffer Delay Com’l/Ind 5 7 11 ns tIO I/O Input Pad and Buffer Delay Com’l/Ind 6 6 11 ns tEXP Expander Array Delay Com’l/Ind 12 14 20 ns tLAD Logic Array Data Delay Com’l/Ind 12 14 14 ns tLAC Logic Array Control Delay Com’l/Ind 10 12 13 ns tOD Output Buffer and Pad Delay[3] Com’l/Ind 5 5 6 ns [3] tZX Output Buffer Enable Delay Com’l/Ind 10 11 13 ns tXZ Output Buffer Disable Delay[7] Com’l/Ind 10 11 13 ns tRSU Register Set-Up Time Relative to Clock Signal at Register Com’l/Ind 6 8 12 ns tRH Register Hold Time Relative to Clock Signal at Register Com’l/Ind 4 6 8 ns tLATCH Flow-Through Latch Delay Com’l/Ind 3 4 4 ns tRD Register Delay Com’l/Ind 1 2 2 ns tCOMB Transparent Mode Delay Com’l/Ind 3 4 4 ns tIC Asynchronous Clock Logic Delay Com’l/Ind 14 16 18 ns tICS Synchronous Clock Delay Com’l/Ind 3 2 1 ns tFD Feedback Delay Com’l/Ind 1 1 2 ns tPRE Asynchronous Register Preset Time Com’l/Ind 5 6 7 ns tCLR Asynchronous Register Clear Time Com’l/Ind 5 6 7 ns tPIA Programmable Interconnect Array Delay Time Com’l/Ind 14 16 20 ns Notes: 6. This parameter is measured with a positive-edge-triggered clock at the register. For negative-edge clocking, the tACH and tACL parameter must be swapped. 7. C1 = 5 pF. Document #: 38-03038 Rev. ** Page 6 of 12 CY7C343B Switching Waveforms Internal Synchronous CLOCK FROM LOGIC ARRAY tOD tRD DATA FROM LOGIC ARRAY tXZ OUTPUT PIN tZX HIGH IMPEDANCE STATE C343B-10 Internal Asynchronous tAWH tIOtR tAWL tF CLOCK PIN tIN CLOCK INTO LOGIC ARRAY tIC CLOCK FROM LOGIC ARRAY tSU tRH DATA FROM LOGIC ARRAY tRD,tLATCH tFD tCLR,tPRE tFD REGISTER OUTPUT TO LOCAL LAB LOGIC ARRAY tPIA REGISTER OUTPUT TO ANOTHER LAB C343B-11 Internal Synchronous SYSTEM CLOCK PIN SYSTEM CLOCK AT REGISTER tIN tICS tRSU tRH DATA FROM LOGIC ARRAY C343B-12 Document #: 38-03038 Rev. ** Page 7 of 12 CY7C343B Switching Waveforms (continued) Internal Combinatorial tIN INPUT PIN t IO I/O PIN tEXP EXPANDER ARRAY DELAY tLAC, tLAD LOGIC ARRAY INPUT LOGIC ARRAY OUTPUT tCOMB tOD OUTPUT PIN C343B-13 External Combinatorial DEDICATED INPUT/ I/O INPUT tPD1/tPD2 COMBINATORIAL OUTPUT C343B-14 External Synchronous tWH tWL SYNCHRONOUS CLOCK PIN SYNCHRONOUS CLOCK AT REGISTER tSU tH DATA FROM LOGIC ARRAY tCO1 REGISTERED OUTPUTS C343B-15 Document #: 38-03038 Rev. ** Page 8 of 12 CY7C343B Switching Waveforms (continued) External Asynchronous DEDICATED INPUTS OR REGISTERED FEEDBACK tAS1 tAH tAWH tAWL ASYNCHRONOUS CLOCK INPUT C343B-16 Ordering Information Speed (ns) 25 Ordering Code Package Name Package Type CY7C343B-25HC/HI H67 44-Pin Windowed Leaded Chip Carrier Operating Range Commercial/Industrial CY7C343B-25JC/JI J67 44-Lead Plastic Leaded Chip Carrier 30 CY7C343B-30JC/JI J67 44-Lead Plastic Leaded Chip Carrier Commercial/Industrial 35 CY7C343B-35HC/HI H67 44-Pin Windowed Leaded Chip Carrier Commercial/Industrial CY7C343B-35JC/JI J67 44-Lead Plastic Leaded Chip Carrier Document #: 38-03038 Rev. ** Page 9 of 12 CY7C343B Package Diagrams 44-Pin Windowed Leaded Chip Carrier H67 51-80079 Document #: 38-03038 Rev. ** Page 10 of 12 CY7C343B Package Diagrams (continued) 44-Lead Plastic Leaded Chip Carrier J67 51-85003-A Document #: 38-03038 Rev. ** Page 11 of 12 © Cypress Semiconductor Corporation, 1999. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a Cypress Semiconductor product. Nor does it convey or imply any license under patent or other rights. Cypress Semiconductor does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress Semiconductor products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress Semiconductor against all charges. CY7C343B Document Title: CY7C343B 64-Macrocell Max ® EPLD Document Number: 38-03038 REV. ECN NO. Issue Date Orig. of Change Description of Change ** 106461 07/11/01 SZV Change from Spec Number: 38-00862 to 38-03038 Document #: 38-03038 Rev. ** Page 12 of 12