QL3025 pASIC 3 FPGA Data Sheet ****** 25,000 Usable PLD Gate pASIC 3 FPGA Combining High Performance and High Density Device Highlights High Performance & High Density * 25,000 Usable PLD Gates with 204 I/Os * 300 MHz 16-bit Counters, 400 MHz Datapaths * 0.35 m four-layer metal non-volatile CMOS process for smallest die sizes Easy to Use / Fast Development Cycles * 100% routable with 100% utilization and complete pin-out stability * Variable-grain logic cells provide high performance and 100% utilization * Comprehensive design tools include high quality Verilog/VHDL synthesis Four Low-Skew Distributed Networks * Two array clock/control networks available to the logic cell flip-flop clock, set and reset inputs -- each driven by an input-only pin * Two global clock/control networks available to the logic cell; F1, clock set, reset inputs and the input, I/O register clock, reset, and enable inputs as well as the output enable control -- each driven by an input-only or I/O pin, or any logic cell output or I/O cell feedback High Performance * Input + logic cell + output total delays under 6 ns * Data path speeds over 400 MHz * Counter speeds over 300 MHz Advanced I/O Capabilities * Interfaces with both 3.3 V and 5.0 V devices * PCI compliant with 3.3 V and 5.0 V buses for -1/-2/-3/-4 speed grades * Full JTAG boundary scan * I/O Cells with individually controlled Registered Input Path and Output Enables Total of 204 I/O Pins * 196 bidirectional input/output pins, PCI-compliant for 5.0 V and 3.3 V buses for -1/-2/-3/-4 speed grades * Four High Drive input-only pins * Four High Drive input-only/distributed network pins Figure 1: 672 pASIC 3 Logic Cells (c) 2002 QuickLogic Corporation www.quicklogic.com * * * * * * 1 QL3025 pASIC 3 FPGA Data Sheet Rev E Architecture Overview The QL3025 is a 25,000 usable PLD gate member of the pASIC 3 family of FPGAs. pASIC 3 FPGAs are fabricated on a 0.35 m four-layer metal process using QuickLogic's patented ViaLink technology to provide a unique combination of high performance, high density, low cost, and extreme ease-of-use. The QL3025 contains 672 logic cells. With a maximum of 204 I/Os, the QL3025 is available in 144-pin TQFP, 208-pin PQFP, and 256-pin PBGA packages. Software support for the complete pASIC 3 family, including the QL3025, is available through three basic packages. The turnkey QuickWorks package provides the most complete FPGA software solution from design entry to logic synthesis, to place and route, to simulation. The QuickToolsTM for Workstations package provides a solution for designers who use Cadence, ExemplarTM, Mentor, Synopsys, Synplicity, ViewlogicTM, AldecTM, or other third-party tools for design entry, synthesis, or simulation. 2 * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E Electrical Specifications AC Characteristics at VCC = 3.3 V, TA = 25C (K = 1.00) To calculate delays, multiply the appropriate K factor from Table 7 by the numbers provided in Table 1 through Table 5. Table 1: Logic Cells Symbol tPD Propagation Delays (ns) Fanouta Parameter Combinatorial Delay b 1 2 3 4 8 1.4 1.7 1.9 2.2 3.2 tSU Setup Time b 1.7 1.7 1.7 1.7 1.7 tH Hold Time 0.0 0.0 0.0 0.0 0.0 tCLK Clock to Q Delay 0.7 1.0 1.2 1.5 2.5 tCWHI Clock High Time 1.2 1.2 1.2 1.2 1.2 tCWLO Clock Low Time 1.2 1.2 1.2 1.2 1.2 tSET Set Delay 1.0 1.3 1.5 1.8 2.8 tRESET Reset Delay 0.8 1.1 1.3 1.6 2.6 tSW Set Width 1.9 1.9 1.9 1.9 1.9 tRW Reset Width 1.8 1.8 1.8 1.8 1.8 a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and TA = 25C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage, and temperature settings as specified in Table 7. b. These limits are derived from a representative selection of the slowest paths through the pASIC 3 logic cell including typical net delays. Worst case delay values for specific paths should be determined from timing analysis of your particular design. Table 2: Input-Only/Clock Cells Symbol Propagation Delays (ns) Fanout a Parameter 1 2 3 4 8 12 24 tIN High Drive Input Delay 1.5 1.6 1.8 1.9 2.4 2.9 4.4 tINI High Drive Input, Inverting Delay 1.6 1.7 1.9 2.0 2.5 3.0 4.5 tISU Input Register Set-Up Time 3.1 3.1 3.1 3.1 3.1 3.1 3.1 tIH Input Register Hold Time 0.0 0.0 0.0 0.0 0.0 0.0 0.0 tlCLK Input Register Clock To Q 0.7 0.8 1.0 1.1 1.6 2.1 3.6 tlRST Input Register Reset Delay 0.6 0.7 0.9 1.0 1.5 2.0 3.5 tlESU Input Register clock Enable Set-Up Time 2.3 2.3 2.3 2.3 2.3 2.3 2.3 tlEH Input Register Clock Enable Hold Time 0.0 0.0 0.0 0.0 0.0 0.0 0.0 a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and TA = 25C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage, and temperature settings as specified in Table 7. * (c) 2002 QuickLogic Corporation www.quicklogic.com ** * * * 3 QL3025 pASIC 3 FPGA Data Sheet Rev E Table 3: Clock Cells Symbol Propagation Delays (ns) Loads per Half Column a Parameter 1 2 3 4 8 10 11 tACK Array Clock Delay 1.2 1.2 1.3 1.3 1.5 1.6 1.7 tGCKP Global Clock Pin Delay 0.7 0.7 0.7 0.7 0.7 0.7 0.7 tGCKB Global Clock Buffer Delay 0.8 0.8 0.9 0.9 1.1 1.2 1.3 a. The array distributed networks consist of 40 half columns and the global distributed networks consist of 44 half columns, each driven by an independent buffer. The number of half columns used does not affect clock buffer delay. The array clock has up to eight loads per half column. The global clock has up to 11 loads per half column. Table 4: Input-Only I/O Cells Symbol Parameter Propagation Delays (ns) Fanout a 1 2 3 4 8 10 tI/O Input Delay (bidirectional pad) 1.3 1.6 1.8 2.1 3.1 3.6 tISU Input Register Set-Up Time 3.1 3.1 3.1 3.1 3.1 3.1 tIH Input Register Hold Time 0.0 0.0 0.0 0.0 0.0 0.0 tlOCLK Input Register Clock To Q 0.7 1.0 1.2 1.5 2.5 3.0 tlORST Input Register Reset Delay 0.6 0.9 1.1 1.4 2.4 2.9 tlESU Input Register clock Enable Set-Up Time 2.3 2.3 2.3 2.3 2.3 2.3 tlEH Input Register Clock Enable Hold Time 0.0 0.0 0.0 0.0 0.0 0.0 a. Stated timing for worst case Propagation Delay over process variation at VCC = 3.3 V and TA = 25C. Multiply by the appropriate Delay Factor, K, for speed grade, voltage, and temperature settings as specified in Table 7. 4 * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E Table 5: Output-Only I/O Cells Symbol Propagation Delays (ns) Output Load Capacitance (pF) Parameter 30 50 75 100 150 tOUTLH Output Delay Low to High 2.1 2.5 3.1 3.6 4.7 tOUTHL Output Delay High to Low 2.2 2.6 3.2 3.7 4.8 tPZH Output Delay Tri-state to High 1.2 1.7 2.2 2.8 3.9 tPZL Output Delay Tri-state to Low 1.6 2.0 2.6 3.1 4.2 tPHZ Output Delay High to Tri-State 2.0 - - - - tPLZ Output Delay Low to Tri-State 1.2 - - - - a a. The following loads presented in Figure 2 are used for tPXZ: tPHZ 1 5 pF 1 tPLZ 5 pF Figure 2: Loads used for tPXZ * (c) 2002 QuickLogic Corporation www.quicklogic.com ** * * * 5 QL3025 pASIC 3 FPGA Data Sheet Rev E DC Characteristics The DC specifications are provided in Table 6 through Table 8. Table 6: Absolute Maximum Ratings Parameter Value Parameter Value VCC Voltage -0.5 V to 4.6 V DC Input Current 20 mA VCCIO Voltage -0.5 V to 7.0 V ESD Pad Protection 2000 V Input Voltage -0.5 V to VCCIO +0.5 V Storage Temperature -65C to +150C Latch-up Immunity 200 mA Lead Temperature 300C Table 7: Operating Range Symbol Military Industrial Commercial Unit Min Max Min Max Min Max Supply Voltage 3.0 3.6 3.0 3.6 3.0 3.6 V I/O Input Tolerance Voltage 3.0 5.5 3.0 5.5 3.0 5.25 V TA Ambient Temperature -55 - -40 85 0 70 C TC Case Temperature - 125 - - - - C -0 Speed Grade - - 0.43 1.90 0.46 1.85 n/a -1 Speed Grade 0.42 1.64 0.43 1.54 0.46 1.50 n/a -2 Speed Grade 0.42 1.37 0.43 1.28 0.46 1.25 n/a -3 Speed Grade 0.43 0.90 0.46 0.88 n/a -4 Speed Grade 0.43 0.82 0.46 0.80 n/a VCC VCCIO K 6 Parameter * * * www.quicklogic.com * * * Delay Factor (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E Table 8: DC Characteristics Symbol Parameter Conditions Min Max Units VIH Input HIGH Voltage 0.5 VCC VCCIO + 0.5 V VIL Input LOW Voltage -0.5 0.3 VCC V VOH Output HIGH Voltage VOL Output LOW Voltage IOH = -12 mA 2.4 V IOH = -500 A 0.9 VCC V IOL = 16 mAa 0.45 V IOL = 1.5 mA 0.1 VCC V II I or I/O Input Leakage Current VI = VCCIO or GND -10 10 A IOZ 3-State Output Leakage Current VI = VCCIO or GND -10 10 A CI Input Capacitanceb 10 pF IOS Output Short Circuit Currentc ICC ICCIO D.C. Supply Current d D.C. Supply Current on VCCIO VO = GND -15 -180 mA VO = VCC 40 210 mA VI, VIO = VCCIO or GND 0.50 (typ) 2 mA 0 100 A a. Applies only to -1/-2/-3/-4 commercial grade devices. These speed grades are also PCI-compliant. All other devices have 8 mA IOL specifications. b. Capacitance is sample tested only. Clock pins are 12 pF maximum. c. Only one output at a time. Duration should not exceed 30 seconds. d. For -1/-2/-3/-4 commercial grade devices only. Maximum ICC is 3 mA for -0 commercial grade and all industrial grade devices, and 5 mA for all military grade devices. For AC conditions, contact QuickLogic customer applications group. (See Contact Information). * (c) 2002 QuickLogic Corporation www.quicklogic.com ** * * * 7 QL3025 pASIC 3 FPGA Data Sheet Rev E Kv and Kt Graphs Voltage Factor vs. Supply Voltage 1.1000 1.0800 1.0600 Kv 1.0400 1.0200 1.0000 0.9800 0.9600 0.9400 0.9200 3 3.1 3.2 3.3 3.4 3.5 3.6 Supply Voltage (V) Figure 3: Voltage Factor vs. Supply Voltage Temperature Factor vs. Operating Temperature 1.15 1.10 1.05 Kt 1.00 0.95 0.90 0.85 -60 -40 -20 0 20 40 60 80 Junction Temperature C Figure 4: Temperature Factor vs. Operating Temperature 8 * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E Power-up Sequencing Voltage VCCIO VCC (VCCIO -VCC)MAX VCC 400 us Time Figure 5: Power-up Requirements The following requirements must be met when powering up the device (refer to Figure 5): * When ramping up the power supplies keep (VCCIO -VCC)MAX 500 mV. Deviation from this recommendation can cause permanent damage to the device. * VCCIO must lead VCC when ramping the device. * The power supply must take greater than or equal to 400 s to reach VCC. Ramping to VCC/VCCIO earlier than 400 s can cause the device to behave improperly. An internal diode is present in-between VCC and VCCIO, as shown in Figure 6. V CC Internal Logic Cells, RAM blocks, etc V CCIO IO Cells Figure 6: Internal Diode Between VCC and VCCIO * (c) 2002 QuickLogic Corporation www.quicklogic.com ** * * * 9 QL3025 pASIC 3 FPGA Data Sheet Rev E JTAG TCK TMS TAp Controller State Machine (16 States) Instruction Decode & Control Logic TRSTB Instruction Register RDI Mux Mux TDO Boundary-Scan Register (Data Register) Bypass Register Internal Register I/O Registers User Defined Data Register Figure 7: JTAG Block Diagram Microprocessors and Application Specific Integrated Circuits (ASICs) pose many design challenges, not the least of which concerns the accessibility of test points. The Joint Test Access Group (JTAG) formed in response to this challenge, resulting in IEEE standard 1149.1, the Standard Test Access Port and Boundary Scan Architecture. The JTAG boundary scan test methodology allows complete observation and control of the boundary pins of a JTAG-compatible device through JTAG software. A Test Access Port (TAP) controller works in concert with the Instruction Register (IR); these allow users to run three required tests, along with several user-defined tests. JTAG tests allow users to reduce system debug time, reuse test platforms and tools, and reuse subsystem tests for fuller verification of higher level system elements. 10 * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E The 1149.1 standard requires the following three tests: * Extest Instruction. The Extest instruction performs a PCB interconnect test. This test places a device into an external boundary test mode, selecting the boundary scan register to be connected between the TAP's Test Data In (TDI) and Test Data Out (TDO) pins. Boundary scan cells are preloaded with test patterns (via the Sample/Preload Instruction), and input boundary cells capture the input data for analysis. * Sample/Preload Instruction. This instruction allows a device to remain in its functional mode, while selecting the boundary scan register to be connected between the TDI and TDO pins. For this test, the boundary scan register can be accessed via a data scan operation, allowing users to sample the functional data entering and leaving the device. * Bypass Instruction. The Bypass instruction allows data to skip a device's boundary scan entirely, so the data passes through the bypass register. The Bypass instruction allows users to test a device without passing through other devices. The bypass register is connected between the TDI and TDO pins, allowing serial data to be transferred through a device without affecting the operation of the device. * (c) 2002 QuickLogic Corporation www.quicklogic.com ** 11 * * * QL3025 pASIC 3 FPGA Data Sheet Rev E Pin Descriptions Table 9: Pin Descriptions Pin Function Description TDI Test Data In for JTAG Hold HIGH during normal operation. Connect to VCC if not used for JTAG. TRSTB Active low Reset for JTAG Hold LOW during normal operation. Connect to ground if not used for JTAG. TMS Test Mode Select for JTAG Hold HIGH during normal operation. Connect to VCC if not used for JTAG. TCK Test Clock for JTAG Hold HIGH or LOW during normal operation. Connect to VCC or ground if not used for JTAG. TDO Test data out for JTAG STM Special Test Mode Output that must be left unconnected if not used for JTAG. Must be grounded during normal operation. I/ACLK High-drive input and/or array Can be configured as either or both. network driver I/GCLK High-drive input and/or global Can be configured as either or both. network driver I High-drive input Use for input signals with high fanout. I/O Input/Output pin Can be configured as an input and/or output. VCC Power supply pin Connect to 3.3 V supply. VCCIO Input voltage tolerance pin GND Ground pin Connect to 5.0 V supply if 5 V input tolerance is required, otherwise connect to 3.3 V supply. Connect to ground. Ordering Information QL 3025 - 1 PQ208 C QuickLogic device pASIC 3 device part number Speed Grade 0 = Quick 1 = Fast 2 = Faster 3 = Faster *4 = Wow Operating Range C = Commercial I = Industrial M = Military Package Code PF144 = 144-pin TQFP PQ208 = 208-pin PQFP PB256 = 256-pin PBGA * Contact QuickLogic regarding availability. (See Contact Information) 12 * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E 144 TQFP Pinout Diagram Pin 109 Pin 1 pASIC 3 QL3025-1PF144C Pin 37 Pin 73 Figure 8: Top View of 144 Pin TQFP 208 PQFP Pinout Diagram Pin 157 Pin 1 pASIC 3 QL3025-1PQ208C Pin 53 Pin 105 Figure 9: Top View of 208 Pin PQFP * (c) 2002 QuickLogic Corporation www.quicklogic.com ** 13 * * * QL3025 pASIC 3 FPGA Data Sheet Rev E 144 TQFP & 208 PQFP Pinout Table Table 10: 144 TQFP & 208 PQFP Pinout Table 14 208 PQFP 144 TQFP Function 208 PQFP 144 TQFP Function 208 PQFP 144 TQFP Function 208 PQFP 144 TQFP Function 208 PQFP 144 TQFP Function 1 NC I/O 43 30 GND 85 60 I/O 127 87 GND 169 117 I/O 2 1 I/O 44 31 I/O 86 61 I/O 128 88 I/O 170 118 I/O 3 2 I/O 45 NC I/O 87 NC I/O 129 89 I 171 119 I/O 4 3 I/O 46 32 I/O 88 62 I/O 130 90 ACLK / I 172 120 I/O 5 NC I/O 47 NC I/O 89 63 I/O 131 91 VCC 173 NC I/O 6 4 I/O 48 33 I/O 90 NC I/O 132 92 I 174 NC I/O 7 5 I/O 49 NC I/O 91 NC I/O 133 93 GCLK / I 175 121 I/O 8 NC I/O 50 34 I/O 92 64 I/O 134 94 VCC 176 NC I/O 9 6 I/O 51 35 I/O 93 NC I/O 135 95 I/O 177 122 GND 10 7 VCC 52 36 I/O 94 65 I/O 136 NC I/O 178 123 I/O 11 NC I/O 53 37 I/O 95 66 GND 137 96 I/O 179 124 I/O 12 NC GND 54 38 TDI 96 67 I/O 138 NC I/O 180 NC I/O 13 8 I/O 55 39 I/O 97 NC VCC 139 97 I/O 181 125 I/O 14 NC I/O 56 NC I/O 98 NC I/O 140 98 I/O 182 126 GND 15 9 I/O 57 40 I/O 99 68 I/O 141 NC I/O 183 127 I/O 16 NC I/O 58 NC I/O 100 69 I/O 142 99 I/O 184 128 I/O 17 10 I/O 59 NC GND 101 NC I/O 143 NC I/O 185 129 I/O 18 11 I/O 60 41 I/O 102 70 I/O 144 100 I/O 186 NC I/O 19 12 I/O 61 42 VCC 103 71 TRSTB 145 NC VCC 187 130 VCCIO 20 13 I/O 62 43 I/O 104 72 TMS 146 101 I/O 188 131 I/O 21 NC I/O 63 NC I/O 105 NC I/O 147 102 GND 189 132 I/O 22 14 I/O 64 44 I/O 106 73 I/O 148 103 I/O 190 NC I/O 23 15 GND 65 45 I/O 107 NC I/O 149 104 I/O 191 133 I/O 24 16 I/O 66 NC I/O 108 74 I/O 150 NC I/O 192 134 I/O 25 17 I 67 46 I/O 109 75 I/O 151 105 I/O 193 NC I/O 26 18 ACLK / I 68 47 I/O 110 76 I/O 152 106 I/O 194 135 I/O 27 19 VCC 69 48 I/O 111 77 I/O 153 NC I/O 195 136 I/O 28 20 I 70 NC I/O 112 NC I/O 154 107 I/O 196 NC I/O 29 21 GCLK / I 71 49 I/O 113 78 I/O 155 NC I/O 197 137 I/O 30 22 VCC 72 NC I/O 114 79 VCC 156 108 I/O 198 NC I/O 31 23 I/O 73 50 GND 115 80 I/O 157 109 TCK 199 138 GND 32 NC I/O 74 51 I/O 116 NC GND 158 110 STM 200 139 I/O 33 24 I/O 75 52 I/O 117 81 I/O 159 111 I/O 201 NC VCC 34 NC I/O 76 NC I/O 118 82 I/O 160 NC I/O 202 140 I/O 35 25 I/O 77 53 I/O 119 NC I/O 161 112 I/O 203 NC I/O 36 NC I/O 78 54 GND 120 83 I/O 162 113 I/O 204 141 I/O 37 26 I/O 79 55 I/O 121 NC I/O 163 NC GND 205 142 I/O 38 27 I/O 80 56 I/O 122 84 I/O 164 NC I/O 206 NC I/O 39 28 I/O 81 NC I/O 123 85 I/O 165 114 VCC 207 143 TDO 40 NC I/O 82 57 I/O 124 NC I/O 166 115 I/O 208 144 I/O 41 NC VCC 83 58 VCCIO 125 86 I/O 167 116 I/O 42 29 I/O 84 59 I/O 126 NC I/O 168 NC I/O * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E 256 PBGA Pinout Diagram pASIC 3 QL3025-1PB256C BOTTOM View 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 PIN A1 CORNER Figure 10: 256-Pin PBGA Pinout Diagram * (c) 2002 QuickLogic Corporation www.quicklogic.com ** 15 * * * QL3025 pASIC 3 FPGA Data Sheet Rev E 256 PBGA Pinout Table Table 11: 256 PBGA Pinout Table 16 256 PBGA Function 256 Function 256 Function 256 Function 256 Function 256 Function A1 VSS C4 I/O E19 I/O L2 ACLK / I T17 I/O V20 I/O A2 I/O C5 I/O E20 I/O L3 I T18 I/O W1 I/O A3 I/O C6 I/O F1 I/O L4 GCLK / I T19 NC W2 I/O A4 I/O C7 I/O F2 I/O L17 VCC T20 I/O W3 TDI A5 I/O C8 I/O F3 I/O L18 I/O U1 I/O W4 I/O A6 I/O C9 VCCIO F4 VCC L19 I/O U2 I/O W5 I/O A7 I/O C10 I/O F17 VCC L20 I/O U3 I/O W6 I/O A8 I/O C11 I/O F18 NC M1 I/O U4 VSS W7 I/O A9 I/O C12 I/O F19 I/O M2 I/O U5 I/O W8 I/O A10 I/O C13 I/O F20 I/O M3 I/O U6 VCC W9 I/O A11 I/O C14 I/O G1 I/O M4 NC U7 I/O W10 I/O A12 I/O C15 I/O G2 NC M17 NC U8 VSS W11 I/O A13 I/O C16 I/O G3 I/O M18 I/O U9 I/O W12 I/O A14 I/O C17 I/O G4 I/O M19 I/O U10 VCC W13 I/O A15 I/O C18 I/O G17 I/O M20 I/O U11 I/O W14 I/O A16 I/O C19 I/O G18 I/O N1 I/O U12 I/O W15 I/O A17 I/O C20 I/O G19 NC N2 I/O U13 VSS W16 I/O A18 I/O D1 I/O G20 I/O N3 I/O U14 I/O W17 I/O A19 TCK D2 I/O H1 I/O N4 VSS U15 VCC W18 I/O A20 I/O D3 I/O H2 I/O N17 VSS U16 I/O W19 I/O B1 TDO D4 VSS H3 I/O N18 I/O U17 VSS W20 TRSTB B2 I/O D5 I/O H4 VSS N19 I/O U18 I/O Y1 I/O B3 I/O D6 VCC H17 VSS N20 I/O U19 I/O Y2 NC B4 I/O D7 I/O H18 I/O P1 I/O U20 I/O Y3 I/O B5 I/O D8 VSS H19 I/O P2 I/O V1 I/O Y4 I/O B6 I/O D9 I/O H20 I/O P3 I/O V2 NC Y5 I/O B7 I/O D10 I/O J1 I/O P4 I/O V3 I/O Y6 I/O B8 I/O D11 VCC J2 I/O P17 I/O V4 I/O Y7 I/O B9 I/O D12 I/O J3 NC P18 I/O V5 I/O Y8 I/O B10 I/O D13 VSS J4 I/O P19 NC V6 I/O Y9 I/O B11 I/O D14 I/O J17 NC P20 I/O V7 I/O Y10 I/O B12 I/O D15 VCC J18 I/O R1 NC V8 I/O Y11 I/O B13 I/O D16 I/O J19 I/O R2 I/O V9 I/O Y12 I/O B14 I/O D17 VSS J20 GCLK / I R3 I/O V10 I/O Y13 I/O B15 I/O D18 I/O K1 I/O R4 VCC V11 I/O Y14 I/O B16 I/O D19 I/O K2 I/O R17 VCC V12 VCCIO Y15 I/O B17 NC D20 I/O K3 I/O R18 I/O V13 I/O Y16 I/O B18 STM E1 NC K4 VCC R19 I/O V14 I/O Y17 I/O B19 NC E2 I/O K17 I R20 I/O V15 I/O Y18 I/O B20 I/O E3 I/O K18 ACLK / I T1 NC V16 I/O Y19 I/O C1 I/O E4 I/O K19 I T2 I/O V17 I/O Y20 NC C2 I/O E17 I/O K20 NC T3 I/O V18 I/O C3 I/O E18 I/O L1 I T4 NC V19 TMS * * * www.quicklogic.com * * * (c) 2002 QuickLogic Corporation QL3025 pASIC 3 FPGA Data Sheet Rev E Contact Information Telephone: 408 990 4000 (US) 416 497 8884 (Canada) 44 1932 57 9011 (Europe) 49 89 930 86 170 (Germany) 852 8106 9091 (Asia) 81 45 470 5525 (Japan) E-mail: info@quicklogic.com Support: support@quicklogic.com Web site: http://www.quicklogic.com/ Revision History Table 12: Revision History Revision Date Comments A not avail. First release. B not avail. C not avail D May 2001 Update of AC/DC Specs and reformat E June 2002 Added Kfactor, Power-up, JTAG and mechanical drawing information. Reformatted. Copyright Information Copyright (c) 2002 QuickLogic Corporation. All Rights Reserved. The information contained in this product brief, and the accompanying software programs are protected by copyright. All rights are reserved by QuickLogic Corporation. QuickLogic Corporation reserves the right to make periodic modifications of this product without obligation to notify any person or entity of such revision. Copying, duplicating, selling, or otherwise distributing any part of this product without the prior written consent of an authorized representative of QuickLogic is prohibited. QuickLogic, QuickWorks, pASIC, and ViaLink are registered trademarks of QuickLogic Corporation. Verilog is a registered trademark of Cadence Design Systems, Inc. All trademarks and registered trademarks are the property of their respective owners. * (c) 2002 QuickLogic Corporation www.quicklogic.com ** 17 * * *