A1010B-2PLG44C

ACT™ 1 Series FPGAs Features • 5V and 3.3V Families fully compatible with JEDEC specifications A security fuse may be programmed to disable all further programming and to protect the design from being copied or reverse engineered. • Up to 2000 Gate Array Gates (6000 PLD equivalent gates) Product Family Profile • Replaces up to 50 TTL Packages A1010B A10V10B A1020B A10V20B 1,200 3,000 30 12 2,000 6,000 50 20 Logic Modules 295 547 • Data Rates to 75 MHz Flip-Flops (maximum) 147 273 • Two In-Circuit Diagnostic Probe Pins Support Speed Analysis to 25 MHz • Built-In High Speed Clock Distribution Network Routing Resources Horizontal Tracks/Channel Vertical Tracks/Column PLICE Antifuse Elements 22 13 112,000 22 13 186,000 • I/O Drive to 10 mA (5 V), 6 mA (3.3 V) User I/Os (maximum) 57 69 • Nonvolatile, User Programmable Packages: • Replaces up to twenty 20-Pin PAL® Packages Device • Design Library with over 250 Macro Functions • Up to 547 Programmable Logic Modules Capacity Gate Array Equivalent Gates PLD Equivalent Gates TTL Equivalent Packages 20-Pin PAL Equivalent Packages • Up to 273 Flip-Flops • Gate Array Architecture Allows Completely Automatic Place and Route • Fabricated in 1.0 micron CMOS technology Description The ACT™ 1 Series of field programmable gate arrays (FPGAs) offers a variety of package, speed, and application combinations. Devices are implemented in silicon gate, 1-micron two-level metal CMOS, and they employ Actel’s PLICE® antifuse technology. The unique architecture offers gate array flexibility, high performance, and instant turnaround through user programming. Device utilization is typically 95 to 100 percent of available logic modules. ACT 1 devices also provide system designers with unique on-chip diagnostic probe capabilities, allowing convenient testing and debugging. Additional features include an on-chip clock driver with a hardwired distribution network. The network provides efficient clock distribution with minimum skew. The user-definable I/Os are capable of driving at both TTL and CMOS drive levels. Available packages include plastic and ceramic J-leaded chip carriers, ceramic and plastic quad flatpacks, and ceramic pin grid array. April 1996 © 1996 Actel Corporation Performance 5 V Data Rate (maximum) 3.3 V Data Rate (maximum) Note: 44 PLCC 68 PLCC 84 PLCC 100 PQFP 100 PQFP 80 VQFP 80 VQFP 84 CPGA 84 CPGA 84 CQFP 44 PLCC 68 PLCC 75 MHz 55 MHz 75 MHz 55 MHz See Product Plan on page 1-286 for package availability. The Designer and Designer Advantage™ Systems The ACT 1 device family is supported by Actel’s Designer and Designer Advantage Systems, allowing logic design implementation with minimum effort. The systems offer Microsoft® Windows™ and X Windows™ graphical user interfaces and integrate with the resident CAE system to provide a complete gate array design environment: schematic capture, simulation, fully automatic place and route, timing verification, and device programming. The systems also include the ACTmap™ VHDL optimization and synthesis tool and the ACTgen™ Macro Builder, a powerful macro function generator for counters, adders, and other structural blocks. 1-283 The systems are available for 386/486/Pentium™ PC and for HP™ and Sun™ workstations and for running Viewlogic®, Mentor Graphics®, Cadence™, OrCAD™, and Synopsys design environments. Figure 1 • Partial View of an ACT 1 Device ACT 1 Device Structure A partial view of an ACT 1 device (Figure 1) depicts four logic modules and distributed horizontal and vertical interconnect tracks. PLICE antifuses, located at intersections of the horizontal and vertical tracks, connect logic module inputs and outputs. During programming, these antifuses are addressed and programmed to make the connections required by the circuit application. The ACT 1 Logic Module The ACT 1 logic module is an 8-input, one-output logic circuit chosen for the wide range of functions it implements and for its efficient use of interconnect routing resources (Figure 2). The logic module can implement the four basic logic functions (NAND, AND, OR, and NOR) in gates of two, three, or four inputs. Each function may have many versions, with different combinations of active-low inputs. The logic module can also implement a variety of D-latches, exclusivity functions, AND-ORs, and OR-ANDs. No dedicated hardwired latches or flip-flops are required in the array, since latches and flip-flops may be constructed from logic modules wherever needed in the application. Figure 2 • ACT 1 Logic Module I/O Buffers Each I/O pin is available as an input, output, three-state, or bidirectional buffer. Input and output levels are compatible with standard TTL and CMOS specifications. Outputs sink or 1-284 A C T ™ 1 S eri es FP G As source 10 mA at TTL levels. See Electrical Specifications for additional I/O buffer specifications. ACT 1 Array Performance Device O rganization Worst-case delays for ACT 1 arrays are calculated in the same manner as for masked array products. A typical delay parameter is multiplied by a derating factor to account for temperature, voltage, and processing effects. However, in an ACT 1 array, temperature and voltage effects are less dramatic than with masked devices. The electrical characteristics of module interconnections on ACT 1 devices remain constant over voltage and temperature fluctuations. Temperature and Voltage Effects ACT 1 devices consist of a matrix of logic modules arranged in rows separated by wiring channels. This array is surrounded by a ring of peripheral circuits including I/O buffers, testability circuits, and diagnostic probe circuits providing real-time diagnostic capability. Between rows of logic modules are routing channels containing sets of segmented metal tracks with PLICE antifuses. Each channel has 22 signal tracks. Vertical routing is permitted via 13 vertical tracks per logic module column. The resulting network allows arbitrary and flexible interconnections between logic modules and I/O modules. As a result, the total derating factor from typical to worst-case for a standard speed ACT 1 array is only 1.19 to 1, compared to 2 to 1 for a masked gate array. Logic Module Size Logic module size also affects performance. A mask programmed gate array cell with four transistors usually implements only one logic level. In the more complex logic module (similar to the complexity of a gate array macro) of an ACT 1 array, implementation of multiple logic levels within a single module is possible. This eliminates interlevel wiring and associated RC delays. The effect is termed “net compression.” Probe Pin ACT 1 devices have two independent diagnostic probe pins. These pins allow the user to observe any two internal signals by entering the appropriate net name in the diagnostic software. Signals may be viewed on a logic analyzer using Actel’s Actionprobe® diagnostic tools. The probe pins can also be used as user-defined I/Os when debugging is finished. Ordering Information A1010 B – 2 PL 84 C Application (Temperature Range) C = Commercial (0 to +70°C) I = Industrial (–40 to +85°C) M = Military (–55 to +125°C) B = MIL-STD-883 Package Lead Count Package Type PL = Plastic J-Leaded Chip Carriers PQ = Plastic Quad Flatpacks CQ = Ceramic Quad Flatpack PG = Ceramic Pin Grid Array VQ = Very Thin Quad Flatpack Speed Grade Blank = Standard Speed –1 = Approximately 15% faster than Standard –2 = Approximately 25% faster than Standard –3 = Approximately 35% faster than Standard Die Revision B = 1.0 micron CMOS Process Part Number A1010 A1020 A10V10 A10V20 = = = = 1200 Gates (5 V) 2000 Gates (5 V) 1200 Gates (3.3 V) 2000 Gates (3.3 V) 1-285 Product Plan Speed Grade* Application Std –1 –2 –3 C I M B 44-pin Plastic Leaded Chip Carrier (PL) ✔ ✔ ✔ ✔ ✔ ✔ — — 68-pin Plastic Leaded Chip Carrier (PL) ✔ ✔ ✔ ✔ ✔ ✔ — — 100-pin Plastic Quad Flatpack (PQ) ✔ ✔ ✔ ✔ ✔ ✔ — — 80-pin Very Thin (1.0 mm) Quad Flatpack (VQ) ✔ ✔ ✔ ✔ ✔ — — — 84-pin Ceramic Pin Grid Array (PG) ✔ ✔ — — ✔ — ✔ ✔ 44-pin Plastic Leaded Chip Carrier (PL) ✔ ✔ ✔ ✔ ✔ ✔ — — 68-pin Plastic Leaded Chip Carrier (PL) ✔ ✔ ✔ ✔ ✔ ✔ — — 84-pin Plastic Leaded Chip Carrier (PL) ✔ ✔ ✔ ✔ ✔ ✔ — — 100-pin Plastic Quad Flatpack (PQ) ✔ ✔ ✔ ✔ ✔ ✔ — — 80-pin Very Thin (1.0 mm) Quad Flatpack (VQ) ✔ ✔ ✔ ✔ ✔ — — — 84-pin Ceramic Pin Grid Array (PG) ✔ ✔ — — ✔ — ✔ ✔ 84-pin Ceramic Quad Flatpack (CQ) ✔ ✔ — — ✔ — ✔ ✔ ✔ ✔ — — — — — — ✔ ✔ — — — — — — ✔ ✔ ✔ — — — — — — — — — ✔ ✔ ✔ — — — — — — — — — A1010B Device A1020B Device A10V10B Device 68-pin Plastic Leaded Chip Carrier (PL) 80-pin Very Thin (1.0 mm) Quad Flatpack (VQ) A10V20B Device 68-pin Plastic Leaded Chip Carrier (PL) 84-pin Plastic Leaded Chip Carrier (PL) 80-pin Very Thin (1.0 mm) Quad Flatpack (VQ) Applications: C I M B = = = = Commercial Availability: ✔ = Available * Speed Grade: –1 = Approx. 15% faster than Standard Industrial P = Planned –2 = Approx. 25% faster than Standard Military — = Not Planned –3 = Approx. 35% faster than Standard MIL-STD-883 Device Resources User I/Os Device Logic Modules Gates 44-pin 68-pin 80-pin 84-pin 100-pin A1010B, A10V10B 295 1200 34 57 57 57 57 A1020B, A10V20B 547 2000 34 57 69 69 69 1-286 A C T ™ 1 S eri es FP G As Pin Description CLK PRA Clock (Input) TTL Clock input for global clock distribution network. The Clock input is buffered prior to clocking the logic modules. This pin can also be used as an I/O. DCLK Diagnostic Clock (Input) TTL Clock input for diagnostic probe and device programming. DCLK is active when the MODE pin is HIGH. This pin functions as an I/O when the MODE pin is LOW. GND Ground Input LOW supply voltage. I/O PRB Input/Output (Input, Output) I/O pin functions as an input, output, three-state, or bidirectional buffer. Input and output levels are compatible with standard TTL and CMOS specifications. Unused I/O pins are automatically driven LOW by the ALS software. MODE Mode (Input) The MODE pin controls the use of multifunction pins (DCLK, PRA, PRB, SDI). When the MODE pin is HIGH, the special functions are active. When the MODE pin is LOW, the pins function as I/O. To provide Actionprobe capability, the MODE pin should be terminated to GND through a 10K resistor so that the MODE pin can be pulled high when required. NC No Connection This pin is not connected to circuitry within the device. Probe A (Output) The Probe A pin is used to output data from any user-defined design node within the device. This independent diagnostic pin is used in conjunction with the Probe B pin to allow real-time diagnostic output of any signal path within the device. The Probe A pin can be used as a user-defined I/O when debugging has been completed. The pin’s probe capabilities can be permanently disabled to protect the programmed design’s confidentiality. PRA is active when the MODE pin is HIGH. This pin functions as an I/O when the MODE pin is LOW. Probe B (Output) The Probe B pin is used to output data from any user-defined design node within the device. This independent diagnostic pin is used in conjunction with the Probe A pin to allow real-time diagnostic output of any signal path within the device. The Probe B pin can be used as a user-defined I/O when debugging has been completed. The pin’s probe capabilities can be permanently disabled to protect the programmed design’s confidentiality. PRB is active when the MODE pin is HIGH. This pin functions as an I/O when the MODE pin is LOW. SDI Serial Data Input (Input) Serial data input for diagnostic probe and device programming. SDI is active when the MODE pin is HIGH. This pin functions as an I/O when the MODE pin is LOW. V CC Supply Voltage Input HIGH supply voltage. Absolute Maximum Ratings 1 Recommended Operating Conditions Free air temperature range Parameter Symbol Parameter Limits Units VCC DC Supply Voltage2 –0.5 to +7.0 Volts VI Input Voltage –0.5 to VCC +0.5 Volts VO Output Voltage –0.5 to VCC +0.5 Volts IIO I/O Sink/Source Current3 ± 20 mA TSTG Storage Temperature –65 to +150 °C Commercial Industrial Military Units Temperature Range1 0 to +70 –40 to +85 –55 to +125 °C Power Supply Tolerance ±5 ± 10 ± 10 %VCC Note: 1. Ambient temperature (TA) used for commercial and industrial; case temperature (TC) used for military. Notes: 1. Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. Exposure to absolute maximum rated conditions for extended periods may affect device reliability. Device should not be operated outside the Recommended Operating Conditions. 2. VPP = VCC , except during device programming. 3. Device inputs are normally high impedance and draw extremely low current. However, when input voltage is greater than VCC + 0.5 V or less than GND – 0.5 V, the internal protection diode will be forward biased and can draw excessive current. 1-287 Electrical Specifications (5V) Commercial Symbol VOH1 Parameter Min. Max. Min. Military Max. Min. Max. Units (IOH = –10 mA)2 2.4 V (IOH = –6 mA) 3.84 V (IOH = –4 mA) VOL1 Industrial (IOL = 10 3.7 mA)2 3.7 V 0.5 (IOL = 6 mA) V 0.33 0.40 0.40 V VIL –0.3 0.8 –0.3 0.8 –0.3 0.8 V VIH 2.0 VCC + 0.3 2.0 VCC + 0.3 2.0 VCC + 0.3 V Input Transition Time tR, tF2 CIO I/O Capacitance2, 3 Standby Current, ICC4 (typical 5 = 1 mA) –10 Leakage Current 500 500 500 ns 10 10 10 pF 3 10 20 mA 10 µA 10 –10 10 –10 Notes: 1. Only one output tested at a time. VCC = min. 2. Not tested, for information only. 3. Includes worst-case 84-pin PLCC package capacitance. VOUT = 0 V, f = 1 MHz. 4. Typical standby current = 1 mA. All outputs unloaded. All inputs = VCC or GND. 5. VO , VIN = VCC or GND. Electrical Specifications (3.3V) Commercial Parameter Min. VOH1 VOL1 Units Max. (IOH = –4 mA) 2.15 V (IOH = –3.2 mA) 2.4 V (IOL = 6 mA) 0.4 V VIL –0.3 0.8 V VIH 2.0 VCC + 0.3 V 500 ns 10 pF 0.75 mA 10 µA Input Transition Time tR, tF2 CIO I/O Capacitance2, 3 Standby Current, ICC4 (typical 5 Leakage Current = 0.3 mA) –10 Notes: 1. Only one output tested at a time. VCC = min. 2. Not tested, for information only. 3. Includes worst-case 84-pin PLCC package capacitance. VOUT = 0 V, f = 1 MHz. 4. Typical standby current = 0.3 mA. All outputs unloaded. All inputs = VCC or GND. 5. VO, VIN = VCC or GND 1-288 A C T ™ 1 S eri es FP G As Package Thermal Characteristics The device junction to case thermal characteristics is θjc, and the junction to ambient air characteristics is θja. The thermal characteristics for θja are shown with two different air flow rates. Maximum junction temperature is 150°C. A sample calculation of the maximum power dissipation for an 84-pin plastic leaded chip carrier at commercial temperature is as follows: Max junction temp. ( ° C ) – Max commercial temp. ( ° C ) 150 ° C – 70 ° C -------------------------------------------------------------------------------------------------------------------------------------------------- = ----------------------------------- = 2.2 W θ ja ( ° C ⁄ W ) 37 ° C ⁄ W Pin Count θjc θja Still Air θja 300 ft/min Units Plastic J-Leaded Chip Carrier 44 68 84 15 13 12 45 38 37 35 29 28 °C/W °C/W °C/W Plastic Quad Flatpack 100 13 48 40 °C/W Very Thin (1.0 mm) Quad Flatpack 80 12 43 35 °C/W Ceramic Pin Grid Array 84 8 33 20 °C/W Ceramic Quad Flatpack 84 5 40 30 °C/W Package Type General Power Equation P = [ICCstandby + ICCactive] * VCC + IOL * VOL * N + IOH * (VCC – VOH) * M The power due to standby current is typically a small component of the overall power. Standby power is calculated below for commercial, worst case conditions. ICC VCC Power 3 mA 5.25 V 15.75 mW (max) 1 mA 5.25 V 5.25 mW (typ) ICCactive is the current flowing due to CMOS switching. 0.75 mA 3.60 V 2.70 mW (max) IOL, IOH are TTL sink/source currents. 0.30 mA 3.30 V 0.99 mW (typ) Where: ICCstandby is the current flowing when no inputs or outputs are changing. VOL, VOH are TTL level output voltages. Active Power Component N equals the number of outputs driving TTL loads to VOL. Power dissipation in CMOS devices is usually dominated by the active (dynamic) power dissipation. This component is frequency dependent, a function of the logic and the M equals the number of outputs driving TTL loads to VOH. An accurate determination of N and M is problematical because their values depend on the family type, design details, and on the system I/O. The power can be divided into two components: static and active. Static Power Component Actel FPGAs have small static power components that result in lower power dissipation than PALs or PLDs. By integrating multiple PALs/PLDs into one FPGA, an even greater reduction in board-level power dissipation can be achieved. external I/O. Active power dissipation results from charging internal chip capacitances of the interconnect, unprogrammed antifuses, module inputs, and module outputs, plus external capacitance due to PC board traces and load device inputs. An additional component of the active power dissipation is the totem-pole current in CMOS transistor pairs. The net effect can be associated with an equivalent capacitance that can be combined with frequency and voltage to represent active power dissipation. 1-289 Equivalent Capacitance CEQM = Equivalent capacitance of logic modules in pF The power dissipated by a CMOS circuit can be expressed by the Equation 1. CEQI = Equivalent capacitance of input buffers in pF CEQO = Equivalent capacitance of output buffers in pF CEQCR = Equivalent capacitance of routed array clock in pF CEQ is the equivalent capacitance expressed in pF. CL = Output lead capacitance in pF VCC is the power supply in volts. fm = Average logic module switching rate in MHz F is the switching frequency in MHz. fn = Average input buffer switching rate in MHz fp = Average output buffer switching rate in MHz fq1 = Average first routed array clock rate in MHz (All families) Power (uW) = CEQ * VCC2 * F (1) Where: Equivalent capacitance is calculated by measuring ICCactive at a specified frequency and voltage for each circuit component of interest. Measurements have been made over a range of frequencies at a fixed value of VCC. Equivalent capacitance is frequency independent so that the results may be used over a wide range of operating conditions. Equivalent capacitance values are shown below. C EQ Values for Actel FPGAs Fixed Capacitance Values for Actel FPGAs (pF) Device Type r1 routed_Clk1 A10V10B A10V20B A1010B A1020B A1010B 41.4 A1020B 68.6 3.2 3.7 A10V10B 40 Input Buffers (CEQI) 10.9 22.1 A10V20B 65 Output Buffers (CEQO) 11.6 31.2 Modules (CEQM) Routed Array Clock Buffer Loads (CEQCR) 4.1 Determining Average Switching Frequency 4.6 To calculate the active power dissipated from the complete design, the switching frequency of each part of the logic must be known. Equation 2 shows a piece-wise linear summation over all components. Power = VCC2 * [(m * CEQM * fm)modules + (n * CEQI* fn)inputs + (p * (CEQO+ CL) * fp)outputs + 0.5 * (q1 * CEQCR * fq1)routed_Clk1 + (r1 * fq1)routed_Clk1] (2) Where: To determine the switching frequency for a design, you must have a detailed understanding of the data input values to the circuit. The following guidelines are meant to represent worst-case scenarios so that they can be generally used to predict the upper limits of power dissipation. These guidelines are as follows: Logic Modules (m) 90% of modules Inputs switching (n) #inputs/4 Outputs switching (p) #outputs/4 First routed array clock loads (q1) 40% of modules Load capacitance (CL) 35 pF m = Number of logic modules switching at fm Average logic module switching rate (fm) F/10 n = Number of input buffers switching at fn Average input switching rate (fn) F/5 p = Number of output buffers switching at fp Average output switching rate (fp) F/10 q1 = Number of clock loads on the first routed array clock (All families) Average first routed array clock rate F (fq1) r1 = Fixed capacitance due to first routed array clock (All families) 1-290 A C T ™ 1 S eri es FP G As Functional Timing Tests AC timing for logic module internal delays is determined after place and route. The DirectTime Analyzer utility displays actual timing parameters for circuit delays. ACT 1 devices are AC tested to a “binning” circuit specification. The circuit consists of one input buffer + n logic modules + one output buffer (n = 16 for A1010B; n = 28 for A1020B). The logic modules are distributed along two sides of the device, as inverting or non-inverting buffers. The modules are connected through programmed antifuses with typical capacitive loading. Propagation delay [tPD = (tPLH + tPHL)/2] is tested to the following AC test specifications. Output Buffer Performance Derating (5V) Source –4 10 –6 IOH (mA) IOL (mA) Sink 12 8 6 4 0.2 –8 –10 0.3 0.4 0.5 –12 4.0 0.6 3.6 VOL (Volts) 3.2 2.8 2.4 2.0 2.0 2.5 VOH (Volts) Military, worst-case values at 125°C, 4.5 V. Commercial, worst-case values at 70°C, 4.75 V. Note: The above curves are based on characterizations of sample devices and are not completely tested on all devices. Output Buffer Performance Derating (3.3V) Source –4 10 –6 IOH (mA) IOL (mA) Sink 12 8 6 4 0.0 –8 –10 0.1 0.2 0.3 0.4 –12 0 0.5 VOL (Volts) 1.0 1.5 VOH (Volts) Commercial, worst-case values at 70°C, 4.75 V. Note: The above curves are based on characterizations of sample devices and are not completely tested on all devices. 1-291 ACT 1 Timing Module* Internal Delays Input Delay I/O Module tINYL = 3.1 ns Predicted Routing Delays Output Delay I/O Module Logic Module tIRD2 = 1.4 ns tDLH = 6.7 ns tIRD1 = 0.9 ns tIRD4 = 3.1 ns tIRD8 = 6.6 ns ARRAY CLOCK tCKH = 5.6 ns tPD = 2.9 ns tCO = 2.9 ns tRD1 = 0.9 ns tRD2 = 1.4 ns tRD4 = 3.1 ns tRD8 = 6.6 ns tENHZ = 11.6 ns FO = 128 FMAX = 70 MHz * Values shown for ACT 1 ‘–3 speed’ devices at worst-case commercial conditions. Predictable Performance: Tight Delay Distributions Propagation delay between logic modules depends on the resistive and capacitive loading of the routing tracks, the interconnect elements, and the module inputs being driven. Propagation delay increases as the length of routing tracks, the number of interconnect elements, or the number of inputs increases. From a design perspective, the propagation delay can be statistically correlated or modeled by the fanout (number of loads) driven by a module. Higher fanout usually requires some paths to have longer routing tracks. The ACT 1 family delivers a very tight fanout delay distribution. This tight distribution is achieved in two ways: by decreasing the delay of the interconnect elements and by decreasing the number of interconnect elements per path. Actel’s patented PLICE antifuse offers a very low resistive/capacitive interconnect. The ACT 1 family’s antifuses, fabricated in 1.0 micron lithography, offer nominal levels of 200 ohms resistance and 7.5 femtofarad (fF) capacitance per antifuse. The ACT 1 fanout distribution is also tight due to the low number of antifuses required for each interconnect path. The ACT 1 family’s proprietary architecture limits the number of antifuses per path to a maximum of four, with 90% of interconnects using two antifuses. 1-292 Timing Characteristics Timing characteristics for ACT 1 devices fall into three categories: family dependent, device dependent, and design dependent. The input and output buffer characteristics are common to all ACT 1 family members. Internal routing delays are device dependent. Design dependency means actual delays are not determined until after placement and routing of the user design is complete. Delay values may then be determined by using the DirectTime Analyzer utility or performing simulation with post-layout delays. Critical Nets and Typical Nets Propagation delays are expressed only for typical nets, which are used for initial design performance evaluation. Critical net delays can then be applied to the most time-critical paths. Critical nets are determined by net property assignment prior to placement and routing. Up to 6% of the nets in a design may be designated as critical, while 90% of the nets in a design are typical. Long Tracks Some nets in the design use long tracks. Long tracks are special routing resources that span multiple rows, columns, or modules. Long tracks employ three and sometimes four antifuse connections. This increases capacitance and resistance, resulting in longer net delays for macros connected to long tracks. Typically, up to 6% of nets in a fully utilized device require long tracks. Long tracks contribute approximately 5 ns to 10 ns delay. This additional delay is represented statistically in higher fanout (FO=8) routing delays in the data sheet specifications section. A C T ™ 1 S eri es FP G As Timing Derating “standard speed” timing parameters, and must be multiplied by the appropriate voltage and temperature derating factors for a given application. A best case timing derating factor of 0.45 is used to reflect best case processing. Note that this factor is relative to the Timing Derating Factor (Tem perature and Voltage) Industrial (Commercial Minimum/Maximum Specification) x Military Min. Max. Min. Max. 0.69 1.11 0.67 1.23 Timing Derating Factor for Designs at Typical Temperature (T J = 25°C) and Voltage (5.0 V) (Commercial Maximum Specification) x 0.85 Temperature and Voltage Derating Factors (normalized to Worst-Case Commercial, T J = 4.75 V, 70°C) –55 –40 0 25 70 85 125 4.50 0.75 0.79 0.86 0.92 1.06 1.11 1.23 4.75 0.71 0.75 0.82 0.87 1.00 1.05 1.16 5.00 0.69 0.72 0.80 0.85 0.97 1.02 1.13 5.25 0.68 0.69 0.77 0.82 0.95 0.98 1.09 5.50 0.67 0.69 0.76 0.81 0.93 0.97 1.08 Junction Temperature and Voltage Derating Curves (normalized to Worst-Case Commercial, TJ = 4.75 V, 70°C) 1.3 Derating Factor 1.2 1.1 125°C 1.0 85°C 70°C 0.9 25°C 0.8 0°C –40°C –55°C 0.7 0.6 4.50 4.75 5.00 5.25 5.50 Voltage (V) Note: This derating factor applies to all routing and propagation delays. 1-293 Temperature and Voltage Deratin g Factors (normalized to Worst-Case Commercial, T J = 3.0 V, 70°C) 0 25 70 2.7 1.05 1.09 1.30 3.0 0.81 0.84 1.00 3.3 0.64 0.67 0.79 3.6 0.62 0.64 0.76 Junction Temperature and Voltage Derating Curves (normalized to Worst-Case Commercial, TJ = 3.0 V, 70°C) 1.3 Derating Factor 1.2 1.1 1.0 0.9 0.8 70°C 0.7 25°C 0°C 0.6 0.5 2.7 3.0 3.3 Voltage (V) Note: 1-294 This derating factor applies to all routing and propagation delays. 3.6 A C T ™ 1 S eri es FP G As Parameter Measurement Output Buffer Delays E D VCC In 50% PAD VOL TRIBUFF PAD To AC test loads (shown below) VCC GND 50% VOH E 1.5 V 1.5 V 50% VCC 50% VCC GND 1.5 V PAD E PAD GND 10% VOL tDHL tDLH tENZL GND 50% VOH 50% 90% 1.5 V tENHZ tENZH tENLZ AC Test Loads Load 1 (Used to measure propagation delay) Load 2 (Used to measure rising/falling edges) VCC GND To the output under test 35 pF R to VCC for tPLZ/tPZL R to GND for tPHZ/tPZH R = 1 kΩ To the output under test 35 pF Input Buffer Delays Module Delays PAD S A B Y INBUF Y VCC 3V PAD 1.5 V 1.5 V VCC Y GND 0V 50% 50% tINYH S, A or B 50% 50% VCC Out GND 50% tPLH GND 50% tPHL VCC Out tINYL 50% tPHL GND 50% tPLH 1-295 Sequential Ti ming Characteristics Flip-Flops and Latches D E CLK Q PRE CLR (Positive edge triggered) tHD D1 tSUD tA tWCLKA CLK tSUENA E tCO Q tRS PRE, CLR tWASYN Note: 1-296 D represents all data functions involving A, B, S for multiplexed flip-flops. A C T ™ 1 S eri es FP G As ACT 1 Timing Characteristics (Worst-Case Commercial Conditions, V CC = 4.75 V, T J = 70°C) 1 Logic Module Propagation Delays ‘–3’ Speed Parameter Description Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Units tPD1 Single Module 2.9 3.4 3.8 4.5 6.5 ns tPD2 Dual Module Macros 6.8 7.8 8.8 10.4 15.1 ns tCO Sequential Clk to Q 2.9 3.4 3.8 4.5 6.5 ns tGO Latch G to Q 2.9 3.4 3.8 4.5 6.5 ns tRS Flip-Flop (Latch) Reset to Q 2.9 3.4 3.8 4.5 6.5 ns Predicted Routing ‘–2’ Speed ‘–1’ Speed ‘Std’ Speed 3.3 V Speed Delays2 tRD1 FO=1 Routing Delay 0.9 1.1 1.2 1.4 2.0 ns tRD2 FO=2 Routing Delay 1.4 1.7 1.9 2.2 3.2 ns tRD3 FO=3 Routing Delay 2.1 2.5 2.8 3.3 4.8 ns tRD4 FO=4 Routing Delay 3.1 3.6 4.1 4.8 7.0 ns tRD8 FO=8 Routing Delay 6.6 7.7 8.7 10.2 14.8 ns Sequential Timing Characteristics3 tSUD Flip-Flop (Latch) Data Input Setup 5.5 6.4 7.2 8.5 10.0 ns tHD4 Flip-Flop (Latch) Data Input Hold 0.0 0.0 0.0 0.0 0.0 ns tSUENA Flip-Flop (Latch) Enable Setup 5.5 6.4 7.2 8.5 10.0 ns tHENA Flip-Flop (Latch) Enable Hold 0.0 0.0 0.0 0.0 0.0 ns tWCLKA Flip-Flop (Latch) Clock Active Pulse Width 6.8 8.0 9.0 10.5 9.8 ns Flip-Flop (Latch) Asynchronous Pulse Width 6.8 8.0 9.0 10.5 9.8 ns tA Flip-Flop Clock Input Period 14.2 16.7 18.9 22.3 20.0 ns fMAX Flip-Flop (Latch) Clock Frequency (FO = 128) tWASYN 70 60 53 45 50 MHz Notes: 1. VCC = 3.0 V for 3.3V specifications. 2. Routing delays are for typical designs across worst-case operating conditions. These parameters should be used for estimating device performance. Post-route timing analysis or simulation is required to determine actual worst-case performance. Post-route timing is based on actual routing delay measurements performed on the device prior to shipment. 3. Setup times assume fanout of 3. Further testing information can be obtained from the DirectTime Analyzer utility. 4. The Hold Time for the DFME1A macro may be greater than 0 ns. Use the Designer 3.0 or later Timer to check the Hold Time for this macro. 1-297 ACT 1 Timing Characteristics (continued) (Worst-Case Commercial Conditions) Input Module Propagation Delays ‘–3’ Speed ‘–2’ Speed ‘–1’ Speed ‘Std’ Speed 3.3 V Speed Parameter Description Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Units tINYH Pad to Y High 3.1 3.5 4.0 4.7 6.8 ns tINYL Pad to Y Low 3.1 3.5 4.0 4.7 6.8 ns Input Module Predicted Routing Delays1 tIRD1 FO=1 Routing Delay 0.9 1.1 1.2 1.4 2.0 ns tIRD2 FO=2 Routing Delay 1.4 1.7 1.9 2.2 3.2 ns tIRD3 FO=3 Routing Delay 2.1 2.5 2.8 3.3 4.8 ns tIRD4 FO=4 Routing Delay 3.1 3.6 4.1 4.8 7.0 ns tIRD8 FO=8 Routing Delay 6.6 7.7 8.7 10.2 14.8 ns FO = 16 FO = 128 4.9 5.6 5.6 6.4 6.4 7.3 7.5 8.6 6.7 7.9 ns FO = 16 FO = 128 6.4 7.0 7.4 8.1 8.4 9.2 9.9 10.8 8.8 10.0 ns Global Clock Network tCKH tCKL tPWH tPWL tCKSW tP fMAX Input Low to High Input High to Low Minimum Pulse Width High FO = 16 FO = 128 6.5 6.8 7.5 8.0 8.5 9.0 10.0 10.5 8.9 9.8 ns Minimum Pulse Width Low FO = 16 FO = 128 6.5 6.8 7.5 8.0 8.5 9.0 10.0 10.5 8.9 9.8 ns Maximum Skew FO = 16 FO = 128 Minimum Period Maximum Frequency FO = 16 FO = 128 FO = 16 FO = 128 1.2 1.8 13.2 14.2 1.3 2.1 15.4 16.7 75 70 1.5 2.4 17.6 18.9 65 60 1.8 2.8 20.9 22.3 57 53 1.5 2.4 18.2 20 48 45 ns ns 55 50 MHz Note: 1. These parameters should be used for estimating device performance. Optimization techniques may further reduce delays by 0 to 4 ns. Routing delays are for typical designs across worst-case operating conditions. Post-route timing analysis or simulation is required to determine actual worst-case performance. Post-route timing is based on actual routing delay measurements performed on the device prior to shipment. 1-298 A C T ™ 1 S eri es FP G As ACT 1 Timing Characteristics (continued) (Worst-Case Commercial Conditions) Output Module Timing ‘–3’ Speed ‘–2’ Speed ‘–1’ Speed ‘Std’ Speed 3.3 V Speed Parameter Description Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Units TTL Output Module Timing1 tDLH Data to Pad High 6.7 7.6 8.7 10.3 15.0 ns tDHL Data to Pad Low 7.5 8.6 9.8 11.5 16.7 ns tENZH Enable Pad Z to High 6.6 7.5 8.6 10.2 14.8 ns tENZL Enable Pad Z to Low 7.9 9.1 10.4 12.2 17.7 ns tENHZ Enable Pad High to Z 10.0 11.6 13.1 15.4 22.4 ns tENLZ Enable Pad Low to Z 9.0 10.4 11.8 13.9 20.2 ns dTLH Delta Low to High 0.06 0.07 0.08 0.09 0.13 ns/pF dTHL Delta High to Low 0.08 0.09 0.10 0.12 0.17 ns/pF CMOS Output Module Timing1 tDLH Data to Pad High 7.9 9.2 10.4 12.2 17.7 ns tDHL Data to Pad Low 6.4 7.2 8.2 9.8 14.2 ns tENZH Enable Pad Z to High 6.0 6.9 7.9 9.2 13.4 ns tENZL Enable Pad Z to Low 8.3 9.4 10.7 12.7 18.5 ns tENHZ Enable Pad High to Z 10.0 11.6 13.1 15.4 22.4 ns tENLZ Enable Pad Low to Z 9.0 10.4 11.8 13.9 20.2 ns dTLH Delta Low to High 0.10 0.11 0.13 0.15 0.22 ns/pF dTHL Delta High to Low 0.06 0.07 0.08 0.09 0.13 ns/pF Notes: 1. Delays based on 35 pF loading. 2. SSO information can be found in the “Simultaneous Switching Output Limits for Actel FPGAs” application note on page 4-125. 1-299 Package Pin Assignments 44-Pin PLCC 68-Pin PLCC 1 68 1 44 68-Pin PLCC 44-Pin PLCC A1010B, A10V10B Function A1020B, A10V20B Functions 4 VCC VCC GND 14 GND GND VCC VCC 15 GND GND 16 VCC VCC 21 VCC VCC 21 GND GND 25 VCC VCC 25 VCC VCC 32 GND GND 32 GND GND 38 VCC VCC 33 CLK, I/O CLK, I/O 49 GND GND 34 MODE MODE 52 CLK, I/O CLK, I/O 35 VCC VCC 54 MODE MODE 36 SDI, I/O SDI, I/O 55 VCC VCC 37 DCLK, I/O DCLK, I/O 56 SDI, I/O SDI, I/O 38 PRA, I/O PRA, I/O 57 DCLK, I/O DCLK, I/O 39 PRB, I/O PRB, I/O 58 PRA, I/O PRA, I/O 43 GND GND 59 PRB, I/O PRB, I/O 66 GND GND A1010B Function A1020B Function 3 VCC VCC 10 GND 14 Signal Signal Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-300 A C T ™ 1 S eri es FP G As Package Pin Assignments (continued) 84-Pin PLCC 1 84 A1020B 84-Pin PLCC Signal A1020B, A10V20B Function 4 VCC 12 NC 18 GND 19 GND 25 VCC 26 VCC 33 VCC 40 GND 46 VCC 60 GND 61 GND 64 CLK, I/O 66 MODE 67 VCC 68 VCC 72 SDI, I/O 73 DCLK, I/O 74 PRA, I/O 75 PRB, I/O 82 GND Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-301 Package Pin Assignments (continued) 100-Pin PQFP 100-Pin PQFP 100 1 Pin A1010B Function A1020B Function Pin A1010B Function A1020B Function 1 2 3 4 5 6 13 19 27 28 29 30 31 32 33 36 37 43 44 48 49 50 51 52 NC NC NC NC NC PRB, I/O GND VCC NC NC NC NC NC NC NC GND GND VCC VCC NC NC NC NC NC NC NC NC NC NC PRB, I/O GND VCC NC NC NC NC I/O I/O I/O GND GND VCC VCC I/O I/O I/O NC NC 53 54 55 56 63 69 77 78 79 80 81 82 86 87 90 92 93 94 95 96 97 98 99 100 NC NC NC VCC GND VCC NC NC NC NC NC NC GND GND CLK, I/O MODE VCC VCC NC NC NC SDI, I/O DCLK, I/O PRA, I/O NC NC NC VCC GND VCC NC NC NC I/O I/O I/O GND GND CLK, I/O MODE VCC VCC I/O I/O I/O SDI, I/O DCLK, I/O PRA, I/O Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-302 A C T ™ 1 S eri es FP G As Package Pin Assignments (continued) 80-Pin VQFP 1 80 80-Pin VQFP A1010B, A10V10B Function A1020B, A10V20B Function Pin A1010B, A10V10B Function A1020B, A10V20B Function 2 NC I/O 47 GND GND 3 NC I/O 50 CLK, I/O CLK, I/O 4 NC I/O 52 MODE MODE 7 GND GND 53 VCC VCC 13 VCC VCC 54 NC I/O 17 NC I/O 55 NC I/O 18 NC I/O 56 NC I/O 19 NC I/O 57 SDI, I/O SDI, I/O 20 VCC VCC 58 DCLK, I/O DCLK, I/O 27 GND GND 59 PRA, I/O PRA, I/O 33 VCC VCC 60 NC NC 41 NC I/O 61 PRB, I/O PRB, I/O 42 NC I/O 68 GND GND 43 NC I/O 74 VCC VCC Pin Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-303 Package Pin Assignments (continued) 84-Pin CPGA 1 2 3 4 5 6 7 8 9 10 11 A B C D E 84-Pin CPGA F G H J K L Orientation Pin (C3) Pin A1010B Function A1020B Function Pin A1010B Function A1020B Function A11 PRA, I/O PRA, I/O E10 VCC VCC B1 NC I/O E11 MODE MODE B2 NC NC F1 VCC VCC B5 VCC VCC F9 CLK, I/O CLK, I/O B7 GND GND F10 GND GND B10 PRB, I/O PRB, I/O G2 VCC VCC B11 SDI, I/O SDI,I/O G10 GND GND C1 NC I/O J2 NC I/O C2 NC I/O J10 NC I/O C10 DCLK, I/O DCLK, I/O K1 NC I/O C11 NC I/O K2 VCC VCC D10 NC I/O K5 GND GND D11 NC I/O K7 VCC VCC E2 GND GND K10 NC I/O E3 GND GND K11 NC I/O E9 VCC VCC L1 NC I/O Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-304 A C T ™ 1 S eri es FP G As Package Pin Assignments (continued) 84-Pin CQFP 84 Pin #1 Index 1 84-Pin CQFP Pin A1020B Function Pin A1020B Function 1 NC 53 CLK, I/O 7 GND 55 MODE 8 GND 56 VCC 14 VCC 57 VCC 15 VCC 61 SDI, I/O 22 VCC 62 DCLK, I/O 29 GND 63 PRA, I/O 35 VCC 64 PRB, I/O 49 GND 71 GND 50 GND 77 VCC Notes: 1. NC: Denotes No Connection 2. All unlisted pin numbers are user I/Os. 3. MODE should be terminated to GND through a 10K resistor to enable Actionprobe usage; otherwise it can be terminated directly to GND. 1-305 1-306