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APA1000-PQ208M

APA1000-PQ208M

  • 厂商:

    ACTEL(微芯科技)

  • 封装:

    BFQFP208

  • 描述:

    IC FPGA 158 I/O 208QFP

  • 数据手册
  • 价格&库存
APA1000-PQ208M 数据手册
v5.8 ProASICPLUS® ® Flash Family FPGAs Features and Benefits High Performance Routing Hierarchy • • • • High Capacity Commercial and Industrial • • • I/O 75,000 to 1 Million System Gates 27 k to 198 kbits of Two-Port SRAM 66 to 712 User I/Os • • Military • • • • • • • 300, 000 to 1 million System Gates 72 k to 198 kbits of Two Port SRAM 158 to 712 User I/Os Reprogrammable Flash Technology • • • • • • • • • • • • • • Flexibility with Choice of Industry-Standard Front-End Tools Efficient Design through Front-End Timing and Gate Optimization ISP Support • In-System Programming (ISP) via JTAG Port SRAMs and FIFOs • ® The Industry’s Most Effective Security Key (FlashLock ) • Low Power • • • PLL with Flexible Phase, Multiply/Divide and Delay Capabilities Internal and/or External Dynamic PLL Configuration Two LVPECL Differential Pairs for Clock or Data Inputs Standard FPGA and ASIC Design Flow 3.3 V, 32-Bit PCI, up to 50 MHz (33 MHz over military temperature) Two Integrated PLLs External System Performance up to 150 MHz Secure Programming Schmitt-Trigger Option on Every Input 2.5 V/3.3 V Support with Individually-Selectable Voltage and Slew Rate Bidirectional Global I/Os Compliance with PCI Specification Revision 2.2 Boundary-Scan Test IEEE Std. 1149.1 (JTAG) Compliant Pin Compatible Packages across the ProASICPLUS Family Unique Clock Conditioning Circuitry 0.22 µm 4 LM Flash-Based CMOS Process Live At Power-Up (LAPU) Level 0 Support Single-Chip Solution No Configuration Device Required Retains Programmed Design during Power-Down/Up Cycles Mil/Aero Devices Operate over Full Military Temperature Range Performance • Ultra-Fast Local and Long-Line Network High-Speed Very Long-Line Network High-Performance, Low Skew, Splittable Global Network 100% Routability and Utilization SmartGen Netlist Generation Ensures Optimal Usage of Embedded Memory Blocks 24 SRAM and FIFO Configurations with Synchronous and Asynchronous Operation up to 150 MHz (typical) Low Impedance Flash Switches Segmented Hierarchical Routing Structure Small, Efficient, Configurable (Combinatorial or Sequential) Logic Cells Table 1 • ProASICPLUS Product Profile Device Maximum System Gates Tiles (Registers) Embedded RAM Bits (k=1,024 bits) Embedded RAM Blocks (256x9) LVPECL PLL Global Networks Maximum Clocks Maximum User I/Os JTAG ISP PCI Package (by pin count) TQFP PQFP PBGA FBGA CQFP2 CCGA/LGA2 Notes: APA075 75,000 3,072 27 k 12 2 2 4 24 158 Yes Yes APA150 150,000 6,144 36k 16 2 2 4 32 242 Yes Yes APA3001 300,000 8,192 72 k 32 2 2 4 32 290 Yes Yes APA450 450,000 12,288 108 k 48 2 2 4 48 344 Yes Yes APA6001 600,000 21,504 126 k 56 2 2 4 56 454 Yes Yes APA750 750,000 32,768 144 k 64 2 2 4 64 562 Yes Yes APA10001 1,000,000 56,320 198 k 88 2 2 4 88 712 Yes Yes 100, 144 208 – 144 100 208 456 144, 256 – 208 456 144, 256 208, 352 – 208 456 144, 256, 484 – 208 456 256, 484, 676 208, 352 624 – 208 456 676, 896 – 208 456 896, 1152 208, 352 624 1. Available as Commercial/Industrial and Military/MIL-STD-883B devices. 2. These packages are available only for Military/MIL-STD-883B devices. June 2009 © 2009 Actel Corporation i See the Actel website for the latest version of the datasheet. ProASICPLUS Flash Family FPGAs Ordering Information APA1000 _ F FG G 1152 I Application (Ambient Temperature Range) Blank = Commercial (0˚C to +70˚C) I = Industrial (-40˚C to +85˚C) PP = Pre-production ES = Engineering Silicon (Room Temperature Only) M = Military (-55˚C to 125˚C) B = MIL-STD-883 Class B Package Lead Count Lead-free packaging Blank = Standard Packaging G = RoHS Compliant Packaging Package Type TQ = Thin Quad Flat Pack (0.5 mm pitch) PQ = Plastic Quad Flat Pack (0.5 mm pitch) FG = Fine Pitch Ball Grid Array (1.0 mm pitch) BG = Plastic Ball Grid Array (1.27 mm pitch) CQ = Ceramic Quad Flat Pack (1.05 mm pitch) CG = Ceramic Column Grid Array (1.27 mm pitch) LG = Land Grid Array (1.27 mm pitch) Speed Grade Blank = Standard Speed F = 20% Slower than Standard Part Number APA075 APA150 APA300 APA450 APA600 APA750 APA1000 ii = = = = = = = 75,000 Equivalent System Gates 150,000 Equivalent System Gates 300,000 Equivalent System Gates 450,000 Equivalent System Gates 600,000 Equivalent System Gates 750,000 Equivalent System Gates 1,000,000 Equivalent System Gates v5.8 ProASICPLUS Flash Family FPGAs Device Resources User I/Os2 Military/MIL-STD-883B Commercial/Industrial Device CCGA/ LGA TQFP TQFP PQFP PBGA FBGA FBGA FBGA FBGA FBGA FBGA CQFP CQFP 100-Pin 144-Pin 208-Pin 456-Pin 144-Pin 256-Pin 484-Pin 676-Pin 896-Pin 1152-Pin 208-Pin 352-Pin 624-Pin APA075 66 APA150 66 APA300 APA450 APA600 107 158 100 158 242 100 186 3 158 4 290 4 100 4 186 3, 4 158 158 4 344 356 4 APA750 158 356 APA1000 158 4 356 4 100 186 186 3 344 3, 4 158 248 158 248 440 158 248 440 3 370 3 454 454 562 5 642 4, 5 712 5 Notes: 1. Package Definitions: TQFP = Thin Quad Flat Pack, PQFP = Plastic Quad Flat Pack, PBGA = Plastic Ball Grid Array, FBGA = Fine Pitch Ball Grid Array, CQFP = Ceramic Quad Flat Pack, CCGA = Ceramic Column Grid Array, LGA = Land Grid Array 2. Each pair of PECL I/Os is counted as one user I/O. 3. FG256 and FG484 are footprint-compatible packages. 4. Military Temperature Plastic Package Offering 5. FG896 and FG1152 are footprint-compatible packages. General Guideline Maximum performance numbers in this datasheet are based on characterized data. Actel does not guarantee performance beyond the limits specified within the datasheet. v5.8 iii ProASICPLUS Flash Family FPGAs Temperature Grade Offerings Package APA075 APA150 TQ100 C, I C, I TQ144 C, I PQ208 C, I BG456 FG144 FG256 C, I APA300 APA450 APA600 APA750 APA1000 C, I C, I, M C, I C, I, M C, I C, I, M C, I C, I, M C, I C, I, M C, I C, I, M C, I C, I, M C, I C, I C, I, M C, I C, I, M C, I C, I, M FG484 FG676 C, I, M FG896 C, I C, I FG1152 C, I, M C, I CQ208 M, B M, B M, B CQ352 M, B M, B M, B M, B M, B CG624 Note: C = Commercial I = Industrial M = Military B = MIL-STD-883 Speed Grade and Temperature Matrix C –F Std. ✓ ✓ I ✓ M, B ✓ Note: C = Commercial I = Industrial M = Military B = MIL-STD-883 iv v5.8 ProASICPLUS Flash Family FPGAs Table of Contents General Description ProASICPLUS Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2 Timing Control and Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-13 Sample Implementations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-16 Adjustable Clock Delay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-16 Clock Skew Minimization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-16 PLL Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-21 Design Environment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-28 ISP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-28 Related Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-29 Package Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-30 Calculating Typical Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-31 Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-34 Tristate Buffer Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-45 Output Buffer Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Input Buffer Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Global Input Buffer Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Predicted Global Routing Delay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-47 1-49 1-51 1-53 Global Routing Skew . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-53 Module Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-54 Sample Macrocell Library Listing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-54 Embedded Memory Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-57 Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-76 Recommended Design Practice for VPN/VPP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-77 Package Pin Assignments 100-Pin TQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1 144-Pin TQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3 208-Pin PQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5 208-Pin CQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-12 352-Pin CQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-16 456-Pin PBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-22 144-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-37 256-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-40 484-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-45 676-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-51 896-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-59 1152-Pin FBGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-69 624-Pin CCGA/LGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-78 Datasheet Information List of Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1 Data Sheet Categories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-8 Export Administration Regulations (EAR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-8 Actel Safety Critical, Life Support, and High-Reliability Applications Policy . . . . . 3-8 v5.8 v ProASICPLUS Flash Family FPGAs General Description The ProASICPLUS family of devices, Actel’s secondgeneration Flash FPGAs, offers enhanced performance over Actel’s ProASIC family. It combines the advantages of ASICs with the benefits of programmable devices through nonvolatile Flash technology. This enables engineers to create high-density systems using existing ASIC or FPGA design flows and tools. In addition, the ProASICPLUS family offers a unique clock conditioning circuit based on two on-board phase-locked loops (PLLs). The family offers up to one million system gates, supported with up to 198 kbits of two-port SRAM and up to 712 user I/Os, all providing 50 MHz PCI performance. combination of fine granularity, flexible routing resources, and abundant Flash switches allow 100% utilization and over 95% routability for highly congested designs. Tiles and larger functions are interconnected through a four-level routing hierarchy. Embedded two-port SRAM blocks with built-in FIFO/RAM control logic can have user-defined depths and widths. Users can also select programming for synchronous or asynchronous operation, as well as parity generations or checking. Advantages to the designer extend beyond performance. Unlike SRAM-based FPGAs, four levels of routing hierarchy simplify routing, while the use of Flash technology allows all functionality to be live at powerup. No external boot PROM is required to support device programming. While on-board security mechanisms prevent access to the program information, reprogramming can be performed in-system to support future design iterations and field upgrades. The device’s architecture mitigates the complexity of ASIC migration at higher user volume. This makes ProASICPLUS a costeffective solution for applications in the networking, communications, computing, and avionics markets. The unique clock conditioning circuitry in each device includes two clock conditioning blocks. Each block provides a PLL core, delay lines, phase shifts (0° and 180°), and clock multipliers/dividers, as well as the circuitry needed to provide bidirectional access to the PLL. The PLL block contains four programmable frequency dividers which allow the incoming clock signal to be divided by a wide range of factors from 1 to 64. The clock conditioning circuit also delays or advances the incoming reference clock up to 8 ns (in increments of 0.25 ns). The PLL can be configured internally or externally during operation without redesigning or reprogramming the part. In addition to the PLL, there are two LVPECL differential input pairs to accommodate high-speed clock and data inputs. The ProASICPLUS family achieves its nonvolatility and reprogrammability through an advanced Flash-based 0.22 μm LVCMOS process with four layers of metal. Standard CMOS design techniques are used to implement logic and control functions, including the PLLs and LVPECL inputs. This results in predictable performance compatible with gate arrays. To support customer needs for more comprehensive, lower-cost, board-level testing, Actel’s ProASICPLUS devices are fully compatible with IEEE Standard 1149.1 for test access port and boundary-scan test architecture. For more information concerning the Flash FPGA implementation, please refer to the "Boundary Scan (JTAG)" section on page 1-11. The ProASICPLUS architecture provides granularity comparable to gate arrays. The device core consists of a Sea-of-Tiles™. Each tile can be configured as a flip-flop, latch, or three-input/one-output logic function by programming the appropriate Flash switches. The ProASICPLUS devices are available in a variety of highperformance plastic packages. Those packages and the performance features discussed above are described in more detail in the following sections. v5.8 1-1 ProASICPLUS Flash Family FPGAs ProASICPLUS Architecture The proprietary ProASICPLUS architecture granularity comparable to gate arrays. the appropriate logic cell inputs and outputs. Dedicated high-performance lines are connected as needed for fast, low-skew global signal distribution throughout the core. Maximum core utilization is possible for virtually any design. provides The ProASICPLUS device core consists of a Sea-of-Tiles (Figure 1-1). Each tile can be configured as a three-input logic function (e.g., NAND gate, D-Flip-Flop, etc.) by programming the appropriate Flash switch interconnections (Figure 1-2 and Figure 1-3 on page 1-3). Tiles and larger functions are connected with any of the four levels of routing hierarchy. Flash switches are distributed throughout the device to provide nonvolatile, reconfigurable interconnect programming. Flash switches are programmed to connect signal lines to ProASICPLUS devices also contain embedded, two-port SRAM blocks with built-in FIFO/RAM control logic. Programming options include synchronous or asynchronous operation, two-port RAM configurations, user defined depth and width, and parity generation or checking. Please see the "Embedded Memory Configurations" section on page 1-23 for more information. RAM Block 256x9 Two-Port SRAM or FIFO Block I/Os Logic Tile RAM Block 256x9 Two Port SRAM or FIFO Block Figure 1-1 • The ProASICPLUS Device Architecture Floating Gate Sensing Switch In Switching Word Switch Out Figure 1-2 • Flash Switch 1 -2 v5.8 ProASICPLUS Flash Family FPGAs Local Routing In 1 Efficient Long-Line Routing In 2 (CLK) In 3 (Reset) Figure 1-3 • Core Logic Tile Live at Power-Up Flash Switch PLUS Unlike SRAM FPGAs, ProASICPLUS uses a live-on-power-up ISP Flash switch as its programming element. The Actel Flash-based ProASIC devices support Level 0 of the live at power-up (LAPU) classification standard. This feature helps in system component initialization, executing critical tasks before the processor wakes up, setting up and configuring memory blocks, clock generation, and bus activity management. The LAPU feature of Flash-based ProASICPLUS devices greatly simplifies total system design and reduces total system cost, often eliminating the need for Complex Programmable Logic Device (CPLD) and clock generation PLLs that are used for this purpose in a system. In addition, glitches and brownouts in system power will not corrupt the ProASICPLUS device's Flash configuration, and unlike SRAM-based FPGAs, the device will not have to be reloaded when system power is restored. This enables the reduction or complete removal of the configuration PROM, expensive voltage monitor, brownout detection, and clock generator devices from the PCB design. Flash-based ProASICPLUS devices simplify total system design, and reduce cost and design risk, while increasing system reliability and improving system initialization time. In the ProASICPLUS Flash switch, two transistors share the floating gate, which stores the programming information. One is the sensing transistor, which is only used for writing and verification of the floating gate voltage. The other is the switching transistor. It can be used in the architecture to connect/separate routing nets or to configure logic. It is also used to erase the floating gate (Figure 1-2 on page 1-2). Logic Tile The logic tile cell (Figure 1-3) has three inputs (any or all of which can be inverted) and one output (which can connect to both ultra-fast local and efficient long-line routing resources). Any three-input, one-output logic function (except a three-input XOR) can be configured as one tile. The tile can be configured as a latch with clear or set or as a flip-flop with clear or set. Thus, the tiles can flexibly map logic and sequential gates of a design. v5.8 1-3 ProASICPLUS Flash Family FPGAs Routing Resources The routing structure of ProASICPLUS devices is designed to provide high performance through a flexible fourlevel hierarchy of routing resources: ultra-fast local resources, efficient long-line resources, high-speed, very long-line resources, and high performance global networks. can in turn access every input of every tile. Active buffers are inserted automatically by routing software to limit the loading effects due to distance and fanout. The ultra-fast local resources are dedicated lines that allow the output of each tile to connect directly to every input of the eight surrounding tiles (Figure 1-4). The high-performance global networks are low-skew, high fanout nets that are accessible from external pins or from internal logic (Figure 1-7 on page 1-7). These nets are typically used to distribute clocks, resets, and other high fanout nets requiring a minimum skew. The global networks are implemented as clock trees, and signals can be introduced at any junction. These can be employed hierarchically with signals accessing every input on all tiles. The efficient long-line resources provide routing for longer distances and higher fanout connections. These resources vary in length (spanning 1, 2, or 4 tiles), run both vertically and horizontally, and cover the entire ProASICPLUS device (Figure 1-5 on page 1-5). Each tile can drive signals onto the efficient long-line resources, which L Inputs L L L L Ultra-Fast Local Lines (connects a tile to the adjacent tile, I/O buffer, or memory block) Output L The high-speed, very long-line resources, which span the entire device with minimal delay, are used to route very long or very high fanout nets. (Figure 1-6 on page 1-6). L L L Figure 1-4 • Ultra-Fast Local Resources 1 -4 v5.8 ProASICPLUS Flash Family FPGAs Spans 1 Tile Spans 2 Tiles Spans 4 Tiles Logic Tile L L L L L L L L L L L L L L L L L L L L L L L L Spans 1 Tile Spans 2 Tiles Spans 4 Tiles Logic Cell L L L L L L Figure 1-5 • Efficient Long-Line Resources v5.8 1-5 ProASICPLUS Flash Family FPGAs High Speed Very Long-Line Resouces PAD RING I/O RING I/O RING PAD RING SRAM SRAM PAD RING Figure 1-6 • High-Speed, Very Long-Line Resources Clock Resources Clock Trees ProASICPLUS The family offers powerful and flexible control of circuit timing through the use of analog circuitry. Each chip has two clock conditioning blocks containing a phase-locked loop (PLL) core, delay lines, phase shifter (0° and 180°), clock multiplier/dividers, and all the circuitry needed for the selection and interconnection of inputs to the global network (thus providing bidirectional access to the PLL). This permits the PLL block to drive inputs and/or outputs via the two global lines on each side of the chip (four total lines). This circuitry is discussed in more detail in the "ProASICPLUS Clock Management System" section on page 1-13. 1 -6 v5.8 One of the main architectural benefits of ProASICPLUS is the set of power- and delay-friendly global networks. ProASICPLUS offers four global trees. Each of these trees is based on a network of spines and ribs that reach all the tiles in their regions (Figure 1-7 on page 1-7). This flexible clock tree architecture allows users to map up to 88 different internal/external clocks in an APA1000 device. Details on the clock spines and various numbers of the family are given in Table 1-1 on page 1-7. The flexible use of the ProASICPLUS clock spine allows the designer to cope with several design requirements. Users implementing clock-resource intensive applications can easily route external or gated internal clocks using global routing spines. Users can also drastically reduce delay penalties and save buffering resources by mapping critical high fanout nets to spines. For design hints on using these features, refer to Actel’s Efficient Use of ProASIC Clock Trees application note. ProASICPLUS Flash Family FPGAs High-Performance Global Network I/O RING PAD RING PAD RING Top Spine Global Networks Global Pads Global Pads Global Spine I/O RING Global Ribs Bottom Spine Scope of Spine (Shaded area plus local RAMs and I/Os) PAD RING Note: This figure shows routing for only one global path. Figure 1-7 • High-Performance Global Network Table 1-1 • Clock Spines APA075 APA150 APA300 APA450 APA600 APA750 APA1000 Global Clock Networks (Trees) 4 4 4 4 4 4 4 Clock Spines/Tree 6 8 8 12 14 16 22 Total Spines 24 32 32 48 56 64 88 Top or Bottom Spine Height (Tiles) 16 24 32 32 48 64 80 Tiles in Each Top or Bottom Spine Total Tiles 512 768 1,024 1,024 1,536 2,048 2,560 3,072 6,144 8,192 12,288 21,504 32,768 56,320 v5.8 1-7 ProASICPLUS Flash Family FPGAs Array Coordinates During many place-and-route operations in Actel’s Designer software tool, it is possible to set constraints that require array coordinates. cells and core cells. In addition, the I/O coordinate system changes depending on the die/package combination. Core cell coordinates start at the lower left corner (represented as (1,1)) or at (1,5) if memory blocks are present at the bottom. Memory coordinates use the same system and are indicated in Table 1-2. The memory coordinates for an APA1000 are illustrated in Figure 1-8. For more information on how to use constraints, see the Designer User’s Guide or online help for ProASICPLUS software tools. Table 1-2 is provided as a reference. The array coordinates are measured from the lower left (0,0). They can be used in region constraints for specific groups of core cells, I/Os, and RAM blocks. Wild cards are also allowed. I/O and cell coordinates are used for placement constraints. Two coordinate systems are needed because there is not a one-to-one correspondence between I/O Table 1-2 • Array Coordinates Logic Tile Min. Device x Memory Rows Max. y x Bottom Top y y y All Min. Max. APA075 1 1 96 32 – (33,33) or (33, 35) 0,0 97, 37 APA150 1 1 128 48 – (49,49) or (49, 51) 0,0 129, 53 APA300 1 5 128 68 (1,1) or (1,3) (69,69) or (69, 71) 0,0 129, 73 APA450 1 5 192 68 (1,1) or (1,3) (69,69) or (69, 71) 0,0 193, 73 APA600 1 5 224 100 (1,1) or (1,3) (101,101) or (101, 103) 0,0 225, 105 APA750 1 5 256 132 (1,1) or (1,3) (133,133) or (133, 135) 0,0 257, 137 APA1000 1 5 352 164 (1,1) or (1,3) (165,165) or (165, 167) 0,0 353, 169 (1,169) Memory Blocks (353,169) (1,167) (352,167) (1,165) (352,165) (1,164) (352,164) Core (1,5) (352,5) (1,3) (352,3) (1,1) (352,1) (0,0) Memory Blocks Figure 1-8 • Core Cell Coordinates for the APA1000 1 -8 v5.8 (353,0) ProASICPLUS Flash Family FPGAs Input/Output Blocks Table 1-3 • ProASICPLUS I/O Power Supply Voltages VDDP To meet complex system demands, the ProASICPLUS family offers devices with a large number of user I/O pins, up to 712 on the APA1000. Table 1-3 shows the available supply voltage configurations (the PLL block uses an independent 2.5 V supply on the AVDD and AGND pins). All I/Os include ESD protection circuits. Each I/O has been tested to 2000 V to the human body model (per JESD22 (HBM)). 2.5 V 3.3 V Input Compatibility 2.5 V 3.3 V Output Drive 2.5 V 3.3 V 3.3V/2.5V Signal Control Six or seven standard I/O pads are grouped with a GND pad and either a VDD (core power) or VDDP (I/O power) pad. Two reference bias signals circle the chip. One protects the cascaded output drivers, while the other creates a virtual VDD supply for the I/O ring. Y Pull-up Control EN I/O pads are fully configurable to provide the maximum flexibility and speed. Each pad can be configured as an input, an output, a tristate driver, or a bidirectional buffer (Figure 1-9 and Table 1-4). A Pad 3.3 V/2.5 V Signal Control Drive Strength and Slew-Rate Control Figure 1-9 • I/O Block Schematic Representation Table 1-4 • I/O Features Function I/O pads configured as inputs I/O pads configured as outputs Description • Selectable 2.5 V or 3.3 V threshold levels • Optional pull-up resistor • Optionally configurable as Schmitt trigger input. The Schmitt trigger input option can be configured as an input only, not a bidirectional buffer. This input type may be slower than a standard input under certain conditions and has a typical hysteresis of 0.35 V. I/O macros with an “S” in the standard I/O library have added Schmitt capabilities. • 3.3 V PCI Compliant (except Schmitt trigger inputs) • Selectable 2.5 V or 3.3 V compliant output signals • 2.5 V – JEDEC JESD 8-5 • 3.3 V – JEDEC JESD 8-A (LVTTL and LVCMOS) • 3.3 V PCI compliant • Ability to drive LVTTL and LVCMOS levels • Selectable drive strengths • Selectable slew rates • I/O pads configured as bidirectional • buffers • Tristate Selectable 2.5 V or 3.3 V compliant output signals 2.5 V – JEDEC JESD 8-5 • 3.3 V – JEDEC JESD 8-A (LVTTL and LVCMOS) • 3.3 V PCI compliant • Optional pull-up resistor • Selectable drive strengths • Selectable slew rates • Tristate v5.8 1-9 ProASICPLUS Flash Family FPGAs Power-Up Sequencing low voltage differential amplifier) and a signal and its complement, PPECL (I/P) (PECLN) and NPECL (PECLREF). The LVPECL input pad cell differs from the standard I/O cell in that it is operated from VDD only. While ProASICPLUS devices are live at power-up, the order of VDD and VDDP power-up is important during system start-up. VDD should be powered up simultaneously with VDDP on ProASICPLUS devices. Failure to follow these guidelines may result in undesirable pin behavior during system start-up. For more information, refer to Actel’s Power-Up Behavior of ProASICPLUS Devices application note. Since it is exclusively an input, it requires no output signal, output enable signal, or output configuration bits. As a special high-speed differential input, it also does not require pull ups. Recommended termination for LVPECL inputs is shown in Figure 1-10. The LVPECL pad cell compares voltages on the PPECL (I/P) pad (as illustrated in Figure 1-11) and the NPECL pad and sends the results to the global MUX (Figure 1-14 on page 1-14). This high-speed, low-skew output essentially controls the clock conditioning circuit. LVPECL Input Pads In addition to standard I/O pads and power pads, ProASICPLUS devices have a single LVPECL input pad on both the east and west sides of the device, along with AVDD and AGND pins to power the PLL block. The LVPECL pad cell consists of an input buffer (containing a LVPECLs are designed to meet LVPECL JEDEC receiver standard levels (Table 1-5). Z 0= 50 Ω PPECL + R = 100 Ω From LVPECL Driver Z 0= 50 Ω Data _ NPECL Figure 1-10 • Recommended Termination for LVPECL Inputs Voltage 2.72 2.125 1.49 0.86 Figure 1-11 • LVPECL High and Low Threshold Values Table 1-5 • Symbol LVPECL Receiver Specifications Parameter Min. Max Units VIH Input High Voltage 1.49 2.72 V VIL Input Low Voltage 0.86 2.125 V VID Differential Input Voltage 0.3 VDD V 1 -1 0 v5.8 ProASICPLUS Flash Family FPGAs Boundary Scan (JTAG) pins are dedicated for boundary-scan test usage. Actel recommends that a nominal 20 kΩ pull-up resistor is added to TDO and TCK pins. ProASICPLUS devices are compatible with IEEE Standard 1149.1, which defines a set of hardware architecture and mechanisms for cost-effective, board-level testing. The basic ProASICPLUS boundary-scan logic circuit is composed of the TAP (test access port), TAP controller, test data registers, and instruction register (Figure 1-12). This circuit supports all mandatory IEEE 1149.1 instructions (EXTEST, SAMPLE/PRELOAD and BYPASS) and the optional IDCODE instruction (Table 1-6). The TAP controller is a four-bit state machine (16 states) that operates as shown in Figure 1-13 on page 1-12. The ’1’s and ‘0’s represent the values that must be present at TMS at a rising edge of TCK for the given state transition to occur. IR and DR indicate that the instruction register or the data register is operating in that state. ProASICPLUS devices have to be programmed at least once for complete boundary-scan functionality to be available. Prior to being programmed, EXTEST is not available. If boundary-scan functionality is required prior to programming, refer to online technical support on the Actel website and search for ProASICPLUS BSDL. Each test section is accessed through the TAP, which has five associated pins: TCK (test clock input), TDI and TDO (test data input and output), TMS (test mode selector) and TRST (test reset input). TMS, TDI and TRST are equipped with pull-up resistors to ensure proper operation when no input data is supplied to them. These I/O I/O I/O I/O I/O TDI Test Data Registers Instruction Register TAP Controller Device Logic TDO I/O TRST I/O TMS I/O TCK I/O Bypass Register I/O I/O I/O I/O I/O Figure 1-12 • ProASICPLUS JTAG Boundary Scan Test Logic Circuit Table 1-6 • Table 1-6 • Boundary-Scan Opcodes Boundary-Scan Opcodes Hex Opcode Hex Opcode EXTEST 00 CLAMP 05 SAMPLE/PRELOAD 01 BYPASS FF IDCODE 0F v5.8 1-11 ProASICPLUS Flash Family FPGAs The TAP controller receives two control inputs (TMS and TCK) and generates control and clock signals for the rest of the test logic architecture. On power-up, the TAP controller enters the Test-Logic-Reset state. To guarantee a reset of the controller from any of the possible states, TMS must remain high for five TCK cycles. The TRST pin may also be used to asynchronously place the TAP controller in the Test-Logic-Reset state. with four fields (lowest significant byte (LSB), ID number, part number and version). The boundary-scan register observes and controls the state of each I/O pin. Each I/O cell has three boundary-scan register cells, each with a serial-in, serial-out, parallel-in, and parallel-out pin. The serial pins are used to serially connect all the boundary-scan register cells in a device into a boundaryscan register chain, which starts at the TDI pin and ends at the TDO pin. The parallel ports are connected to the internal core logic tile and the input, output, and control ports of an I/O buffer to capture and load data into the register to control or observe the logic state of each I/O. ProASICPLUS devices support three types of test data registers: bypass, device identification, and boundary scan. The bypass register is selected when no other register needs to be accessed in a device. This speeds up test data transfer to other devices in a test data path. The 32-bit device identification register is a shift register 1 Test-Logic Reset 0 0 Run-Test/ Idle 1 1 Select-DRScan 0 Capture-DR 1 Capture-IR 1 0 0 0 Shift-DR 0 0 1 1 Exit-IR 0 1 1 Exit2-DR 1 Update-DR 0 1 Figure 1-13 • TAP Controller State Diagram 1 -1 2 v5.8 0 Pause-IR Pause-DR 0 0 Shift-IR 1 Exit-DR 1 Select-IRScan 0 0 Exit2-IR 1 Update-IR 0 1 1 ProASICPLUS Flash Family FPGAs Timing Control and Characteristics ProASICPLUS follows (Figure 1-15 on page 1-15, Table 1-7 on page 115, and Table 1-8 on page 1-16): Global A (secondary clock) • • Clock Management System ProASICPLUS devices provide designers with very flexible clock conditioning capabilities. Each member of the ProASICPLUS family contains two phase-locked loop (PLL) blocks which perform the following functions: • Clock Phase Adjustment via Programmable Delay (250 ps steps from –7 ns to +8 ns) • Clock Skew Minimization • Clock Frequency Synthesis • • Output from Global MUX A Conditioned version of PLL output (fOUT) – delayed or advanced Divided version of either of the above Further delayed version of either of the above (0.25 ns, 0.50 ns, or 4.00 ns delay)1 Global B • • • • Each PLL has the following key features: Output from Global MUX B Delayed or advanced version of fOUT Divided version of either of the above Further delayed version of either of the above (0.25 ns, 0.50 ns, or 4.00 ns delay)2 • Input Frequency Range (fIN) = 1.5 to 180 MHz • Feedback Frequency Range (fVCO) = 24 to 180 MHz • Output Frequency Range (fOUT) = 8 to 180 MHz Functional Description • Output Phase Shift = 0 ° and 180 ° • Output Duty Cycle = 50% • Low Output Jitter (max at 25°C) Each PLL block contains four programmable dividers as shown in Figure 1-14 on page 1-14. These allow frequency scaling of the input clock signal as follows: – fVCO 60 MHz. Jitter ±1% or better • • Note: Jitter(ps) = Jitter(%)* period • For Example: Jitter in picoseconds at 100 MHz = 0.01 * (1/100E6) = 100 ps • • Maximum Acquisition = 80 µs for fVCO > 40 MHz Time = 30 µs for fVCO < 40 MHz • Low Power Consumption – 6.9 mW (max – analog supply) + 7.0μW/MHz (max – digital supply) The n divider divides the input clock by integer factors from 1 to 32. The m divider in the feedback path allows multiplication of the input clock by integer factors ranging from 1 to 64. The two dividers together can implement any combination of multiplication and division resulting in a clock frequency between 24 and 180 MHz exiting the PLL core. This clock has a fixed 50% duty cycle. The output frequency of the PLL core is given by the formula EQ 1-1 (fREF is the reference clock frequency): fOUT = fREF * m/n EQ 1-1 Physical Implementation • Each side of the chip contains a clock conditioning circuit based on a 180 MHz PLL block (Figure 1-14 on page 114). Two global multiplexed lines extend along each side of the chip to provide bidirectional access to the PLL on that side (neither MUX can be connected to the opposite side's PLL). Each global line has optional LVPECL input pads (described below). The global lines may be driven by either the LVPECL global input pad or the outputs from the PLL block, or both. Each global line can be driven by a different output from the PLL. Unused global pins can be configured as regular I/Os or left unconnected. They default to an input with pull-up. The two signals available to drive the global networks are as The third and fourth dividers (u and v) permit the signals applied to the global network to each be further divided by integer factors ranging from 1 to 4. The implementations shown in EQ2 and EQ3 enable the user to define a wide range of frequency multiplier and divisors. fGLB = m/(n*u) EQ 1-2 fGLA = m/(n*v) EQ 1-3 1. This mode is available through the delay feature of the Global MUX driver. v5.8 1-13 ProASICPLUS Flash Family FPGAs enable the user to define a wide range of frequency multipliers and divisors. The clock conditioning circuit can advance or delay the clock up to 8 ns (in increments of 0.25 ns) relative to the positive edge of the incoming reference clock. The system also allows for the selection of output frequency clock phases of 0° and 180°. signals relative to other signals to assist in the control of input set-up times. Not all possible combinations of input and output modes can be used. The degrees of freedom available in the bidirectional global pad system and in the clock conditioning circuit have been restricted. This avoids unnecessary and unwieldy design kit and software work. Prior to the application of signals to the rib drivers, they pass through programmable delay units, one per global network. These units permit the delaying of global AVDD AGND VDD GND GLA Global MUX B OUT Input Pins to the PLL See Figure 1-15 + 1-14 on page - Clock Conditioning Circuitry (Top level view) External Feedback Signal GLB 27 4 Global MUX A OUT 8 Flash Configuration Bits Dynamic Configuration Bits Clock Conditioning Circuitry Detailed Block Diagram CLK Bypass Primary 1 P+ FIVDIV[4:0] P- 7 ÷n PLL Core 180˚ ÷m 0˚ FBDIV[5:0] Clock from Core (GLINT mode) 6 5 4 0 ÷u DLYB[1:0] Delay Line 0.0 ns, 0.25 ns, 0.50 ns and 4.00 ns OBDIV[1:0] 1 1 Delay Line 0.25 ns to 4.00 ns, 16 steps, 0.25 ns increments XDLYSEL Deskew Delay 2.95 ns 2 3 FBDLY[3:0] FBSEL[1:0] 3 OADIV[1:0] 2 ÷v DLYA[1:0] Delay Line 0.0 ns, 0.25 ns, 0.50 ns and 4.00 ns 1 OAMUX[1:0] CLKA Bypass Secondary Clock from Core (GLINT mode) Notes: 1. FBDLY is a programmable delay line from 0 to 4 ns in 250 ps increments. 2. DLYA and DLYB are programmable delay lines, each with selectable values 0 ps, 250 ps, 500 ps, and 4 ns. 3. OBDIV will also divide the phase-shift since it takes place after the PLL Core. Figure 1-14 • PLL Block – Top-Level View and Detailed PLL Block Diagram 1 -1 4 GLB 2 0 EXTFB OBMUX[2:0] v5.8 GLA ProASICPLUS Flash Family FPGAs Package Pins GL Physical I/O Buffers Global MUX Configuration Tile Std. Pad Cell Global MUX B OUT NPECL PECL Pad Cell PPECL External Feedback GLMX Std. Pad Cell GL Std. Pad Cell Global MUX A OUT Configuration Tile CORE Legend Physical Pin DATA Signals to the Global MUX DATA Signals to the Core Control Signals to the Global MUX DATA Signals to the PLL Block Note: When a signal from an I/O tile is connected to the core, it cannot be connected to the Global MUX at the same time. Figure 1-15 • Input Connectors to ProASICPLUS Clock Conditioning Circuitry Table 1-7 • Clock-Conditioning Circuitry MUX Settings MUX Datapath Comments FBSEL 1 Internal Feedback 2 Internal Feedback and Advance Clock Using FBDLY 3 External Feedback (EXTFB) –0.25 to –4 ns in 0.25 ns increments XDLYSEL 0 Feedback Unchanged 1 Deskew feedback by advancing clock by system delay OBMUX Fixed delay of -2.95 ns GLB 0 Primary bypass, no divider 1 Primary bypass, use divider 2 Delay Clock Using FBDLY 4 Phase Shift Clock by 0° 5 Reserved 6 Phase Shift Clock by +180° 7 Reserved OAMUX +0.25 to +4 ns in 0.25 ns increments GLA 0 Secondary bypass, no divider 1 Secondary bypass, use divider 2 Delay Clock Using FBDLY 3 Phase Shift Clock by 0° +0.25 to +4 ns in 0.25 ns increments v5.8 1-15 ProASICPLUS Flash Family FPGAs Table 1-8 • Sample Implementations Clock-Conditioning Circuitry Delay-Line Settings Delay Line Delay Value (ns) Frequency Synthesis DLYB 0 0 1 +0.25 2 +0.50 3 +4.0 DLYA 0 0 1 +0.25 2 +0.50 3 +4.0 Lock Signal An active-high Lock signal (added via the SmartGen PLL development tool) indicates that the PLL has locked to the incoming clock signal. The PLL will acquire and maintain lock even when there is jitter on the incoming clock signal. The PLL will maintain lock with an input jitter up to 5% of the input period, with a maximum of 5 ns. Users can employ the Lock signal as a soft reset of the logic driven by GLB and/or GLA. Note if FIN is not within specified frequencies, then both the FOUT and lock signal are indeterminate. PLL Configuration Options The PLL can be configured during design (via Flashconfiguration bits set in the programming bitstream) or dynamically during device operation, thus eliminating the need to reprogram the device. The dynamic configuration bits are loaded into a serial-in/parallel-out shift register provided in the clock conditioning circuit. The shift register can be accessed either from user logic within the device or via the JTAG port. Another option is internal dynamic configuration via user-designed hardware. Refer to Actel's ProASICPLUS PLL Dynamic Reconfiguration Using JTAG application note for more information. For information on the clock conditioning circuit, refer to Actel’s Using ProASICPLUS Clock Conditioning Circuits application note. 1 -1 6 v5.8 Figure 1-16 on page 1-17 illustrates an example where the PLL is used to multiply a 33 MHz external clock up to 133 MHz. Figure 1-17 on page 1-17 uses two dividers to synthesize a 50 MHz output clock from a 40 MHz input reference clock. The input frequency of 40 MHz is multiplied by five and divided by four, giving an output clock (GLB) frequency of 50 MHz. When dividers are used, a given ratio can be generated in multiple ways, allowing the user to stay within the operating frequency ranges of the PLL. For example, in this case the input divider could have been two and the output divider also two, giving us a division of the input frequency by four to go with the feedback loop division (effective multiplication) by five. Adjustable Clock Delay Figure 1-18 on page 1-18 illustrates the delay of the input clock by employing one of the adjustable delay lines. This is easily done in ProASICPLUS by bypassing the PLL core entirely and using the output delay line. Notice also that the output clock can be effectively advanced relative to the input clock by using the delay line in the feedback path. This is shown in Figure 1-19 on page 1-18. Clock Skew Minimization Figure 1-20 on page 1-19 indicates how feedback from the clock network can be used to create minimal skew between the distributed clock network and the input clock. The input clock is fed to the reference clock input of the PLL. The output clock (GLA) feeds a clock network. The feedback input to the PLL uses a clock input delayed by a routing network. The PLL then adjusts the phase of the input clock to match the delayed clock, thus providing nearly zero effective skew between the two clocks. Refer to Actel's Using ProASICPLUS Clock Conditioning Circuits application note for more information. ProASICPLUS Flash Family FPGAs Global MUX B OUT 33 MHz ÷1 ÷n 180˚ PLL Core 0˚ ÷m ÷4 ÷u ÷1 D GLB 133 MHz D D External Feedback ÷v D GLA Global MUX A OUT Figure 1-16 • Using the PLL 33 MHz In, 133 MHz Out Global MUX B OUT 40 MHz ÷4 ÷n 180˚ PLL Core ÷m 0˚ ÷u ÷1 GLB D 50 MHz ÷5 D D External Feedback ÷v D GLA Global MUX A OUT Figure 1-17 • Using the PLL 40 MHz In, 50 MHz Out v5.8 1-17 ProASICPLUS Flash Family FPGAs Global MUX B OUT 133 MHz ÷1 ÷n 180˚ PLL Core ÷m 0˚ ÷1 ÷u ÷1 GLB D 133 MHz D D External Feedback ÷v D GLA Global MUX A OUT Figure 1-18 • Using the PLL to Delay the Input Clock Global MUX B OUT 133 MHz ÷1 ÷n 180˚ PLL Core 0˚ ÷m ÷u ÷1 GLB D 133 MHz ÷1 D D External Feedback ÷v Global MUX A OUT Figure 1-19 • Using the PLL to Advance the Input Clock 1 -1 8 v5.8 D GLA ProASICPLUS Flash Family FPGAs Off chip Global MUX B OUT On chip /1 180˚ ÷n 133 MHz PLL Core 0˚ ÷m ÷u D GL B /1 D External Feedback D 133 MHz ÷v Global MUX A OUT Reference clock Q SET D GL A D Q CLR Figure 1-20 • Using the PLL for Clock Deskewing v5.8 1-19 ProASICPLUS Flash Family FPGAs Logic Tile Timing Characteristics Timing Derating ProASICPLUS Timing characteristics for devices fall into three categories: family dependent, device dependent, and design dependent. The input and output buffer characteristics are common to all ProASICPLUS family members. Internal routing delays are device dependent. Design dependency means that actual delays are not determined until after placement and routing of the user’s design are complete. Delay values may then be determined by using the Timer utility or by performing simulation with post-layout delays. Since ProASICPLUS devices are manufactured with a CMOS process, device performance will vary with temperature, voltage, and process. Minimum timing parameters reflect maximum operating voltage, minimum operating temperature, and optimal process variations. Maximum timing parameters reflect minimum operating voltage, maximum operating temperature, and worst-case process variations (within process specifications). The derating factors shown in Table 1-9 should be applied to all timing data contained within this datasheet. Critical Nets and Typical Nets All timing numbers listed in this datasheet represent sample timing characteristics of ProASICPLUS devices. Actual timing delay values are design-specific and can be derived from the Timer tool in Actel’s Designer software after place-and-route. 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 timing-critical paths. Critical nets are determined by net property assignment prior to place-and-route. Refer to the Actel Designer User’s Guide or online help for details on using constraints. Table 1-9 • Temperature and Voltage Derating Factors (Normalized to Worst-Case Commercial, TJ = 70°C, VDD = 2.3 V) –55°C –40°C 0°C 25°C 70°C 85°C 110°C 125°C 135°C 150°C 2.3 V 0.84 0.86 0.91 0.94 1.00 1.02 1.05 1.13 1.18 1.27 2.5 V 0.81 0.82 0.87 0.90 0.95 0.98 1.01 1.09 1.13 1.21 2.7 V 0.77 0.79 0.83 0.86 0.91 0.93 0.96 1.04 1.08 1.16 Notes: 1. The user can set the junction temperature in Designer software to be any integer value in the range of –55°C to 175°C. 2. The user can set the core voltage in Designer software to be any value between 1.4 V and 1.6 V. 1 -2 0 v5.8 ProASICPLUS Flash Family FPGAs PLL Electrical Specifications Parameter Value TJ ≤ –40°C Value TJ > –40°C Notes Frequency Ranges Reference Frequency fIN (min.) 2.0 MHz 1.5 MHz Clock conditioning circuitry (min.) lowest input frequency Reference Frequency fIN (max.) 180 MHz 180 MHz Clock conditioning circuitry (max.) highest input frequency OSC Frequency fVCO (min.) 60 24 MHz Lowest output frequency voltage controlled oscillator OSC Frequency fVCO (max.) 180 180 MHz Highest output frequency voltage controlled oscillator Clock Conditioning Circuitry fOUT (min.) fIN ≤ 40 = 18 MHz fIN > 40 = 16 MHz 6 MHz Lowest output frequency clock conditioning circuitry Clock Conditioning Circuitry fOUT (max.) 180 180 MHz Highest output frequency clock conditioning circuitry Acquisition Time from Cold Start Acquisition Time (max.) 80 μs 30 μs fVCO ≤ 40 MHz Acquisition Time (max.) 80 μs 80 μs fVCO > 40 MHz Long Term Jitter Peak-to-Peak Max.* Temperature Frequency MHz fVCO< 1060 MHz) under typical setup conditions v5.8 1-21 ProASICPLUS Flash Family FPGAs PLL I/O Constraints PLL locking is guaranteed only when the following constraints are followed: Table 1-10 • PLL I/O Constraints TJ ≤ –40°C Value TJ > –40°C I/O Type PLL locking is guaranteed only when using low drive strength and low slew rate I/O. PLL locking may be inconsistent when using high drive strength or high slew rate I/Os No Constraints SSO APA300 Hermetic packages ≤ 8 SSO Plastic packages ≤ 16 SSO APA600 With FIN ≤ 180 MHz and outputs switching simultaneously Hermetic packages ≤ 16 SSO Plastic packages ≤ 32 SSO APA1000 Hermetic packages ≤ 16 SSO Plastic packages ≤ 32 SSO APA300 Hermetic packages ≤ 12 SSO Plastic packages ≤ 20 SSO APA600 Hermetic packages ≤ 32 SSO Plastic packages ≤ 64 SSO APA1000 Hermetic packages ≤ 32 SSO Plastic packages ≤ 64 SSO 1 -2 2 v5.8 With FIN ≤ 50 MHz and half outputs switching on positive clock edge, half switching on the negative clock edge no less than 10nsec later ProASICPLUS Flash Family FPGAs ® User Security Embedded Memory Configurations ProASICPLUS The embedded memory in the ProASICPLUS family provides great configuration flexibility (Table 1-12). Each ProASICPLUS block is designed and optimized as a twoport memory (one read, one write). This provides 198 kbits of two-port and/or single port memory in the APA1000 device. devices have FlashLock protection bits that, once programmed, block the entire programmed contents from being read externally. Please refer to Table 1-11 for details on the number of bits in the key for each device. If locked, the user can only reprogram the device employing the user-defined security key. This protects the device from being read back and duplicated. Since programmed data is stored in nonvolatile memory cells (actually very small capacitors) rather than in the wiring, physical deconstruction cannot be used to compromise data. This type of security breach is further discouraged by the placement of the memory cells beneath the four metal layers (whose removal cannot be accomplished without disturbing the charge in the capacitor). This is the highest security provided in the industry. For more information, refer to Actel’s Design Security in Nonvolatile Flash and Antifuse FPGAs white paper. Each memory block can be configured as FIFO or SRAM, with independent selection of synchronous or asynchronous read and write ports (Table 1-13). Additional characteristics include programmable flags as well as parity checking and generation. Figure 1-21 on page 1-25 and Figure 1-22 on page 1-26 show the block diagrams of the basic SRAM and FIFO blocks. Table 1-14 on page 1-25 and Table 1-15 on page 1-26 describe memory block SRAM and FIFO interface signals, respectively. A single memory block is designed to operate at up to 150 MHz (standard speed grade typical conditions). Each block is comprised of 256 9-bit words (one read port, one write port). The memory blocks may be cascaded in width and/or depth to create the desired memory organization. (Figure 1-23 on page 1-27). This provides optimal bit widths of 9 (one block), 18, 36, and 72, and optimal depths of 256, 512, 768, and 1,024. Refer to Actel’s SmartGen User’s Guide for more information. Table 1-11 • Flashlock Key Size by Device Device Key Size APA075 79 bits APA150 79 bits APA300 79 bits APA450 119 bits APA600 167 bits APA750 191 bits APA1000 263 bits Figure 1-24 on page 1-27 gives an example of optimal memory usage. Ten blocks with 23,040 bits have been used to generate three arrays of various widths and depths. Figure 1-25 on page 1-27 shows how RAM blocks can be used in parallel to create extra read ports. In this example, using only 10 of the 88 available blocks of the APA1000 yields an effective 6,912 bits of multiple port RAM. The Actel SmartGen software facilitates building wider and deeper memory configurations for optimal memory usage. Embedded Memory Floorplan The embedded memory is located across the top and bottom of the device in 256x9 blocks (Figure 1-1 on page 1-2). Depending on the device, up to 88 blocks are available to support a variety of memory configurations. Each block can be programmed as an independent memory array or combined (using dedicated memory routing resources) to form larger, more complex memory configurations. A single memory configuration could include blocks from both the top and bottom memory locations. Table 1-12 • ProASICPLUS Memory Configurations by Device Maximum Width Maximum Depth Device Bottom Top D W D W APA075 APA150 APA300 APA450 APA600 0 0 16 24 28 12 16 16 24 28 256 256 256 256 256 108 144 144 216 252 1,536 2,048 2,048 3,072 3,584 9 9 9 9 9 v5.8 1-23 ProASICPLUS Flash Family FPGAs Table 1-12 • ProASICPLUS Memory Configurations by Device Maximum Width Maximum Depth Device Bottom Top D W D W APA750 APA1000 32 44 32 44 256 256 288 396 4,096 5,632 9 9 Table 1-13 • Basic Memory Configurations Type Write Access Read Access Parity Library Cell Name RAM Asynchronous Asynchronous Checked RAM256x9AA RAM Asynchronous Asynchronous Generated RAM256x9AAP RAM Asynchronous Synchronous Transparent Checked RAM256x9AST RAM Asynchronous Synchronous Transparent Generated RAM256x9ASTP RAM Asynchronous Synchronous Pipelined Checked RAM256x9ASR RAM Asynchronous Synchronous Pipelined Generated RAM256x9ASRP RAM Synchronous Asynchronous Checked RAM256x9SA RAM Synchronous Asynchronous Generated RAM256xSAP RAM Synchronous Synchronous Transparent Checked RAM256x9SST RAM Synchronous Synchronous Transparent Generated RAM256x9SSTP RAM Synchronous Synchronous Pipelined Checked RAM256x9SSR RAM Synchronous Synchronous Pipelined Generated RAM256x9SSRP FIFO Asynchronous Asynchronous Checked FIFO256x9AA FIFO Asynchronous Asynchronous Generated FIFO256x9AAP FIFO Asynchronous Synchronous Transparent Checked FIFO256x9AST FIFO Asynchronous Synchronous Transparent Generated FIFO256x9ASTP FIFO Asynchronous Synchronous Pipelined Checked FIFO256x9ASR FIFO Asynchronous Synchronous Pipelined Generated FIFO256x9ASRP FIFO Synchronous Asynchronous Checked FIFO256x9SA FIFO Synchronous Asynchronous Generated FIFO256x9SAP FIFO Synchronous Synchronous Transparent Checked FIFO256x9SST FIFO Synchronous Synchronous Transparent Generated FIFO256x9SSTP FIFO Synchronous Synchronous Pipelined Checked FIFO256x9SSR FIFO Synchronous Synchronous Pipelined Generated FIFO256x9SSRP 1 -2 4 v5.8 ProASICPLUS Flash Family FPGAs DI WADDR DO RADDR SRAM (256x9) WRB WBLKB RDB RBLKB RCLKS Sync Write and Sync Read Ports WCLKS WPE DI WADDR WRB WBLKB WPE RPE PARODD DI WADDR DO RADDR WPE DI WADDR WRB WBLKB RDB RBLKB Sync Write and Async Read Ports WCLKS Async Write and Async Read Ports DO RADDR RDB RBLKB RCLKS RPE PARODD SRAM (256x9) WRB WBLKB SRAM (256x9) RPE WPE PARODD SRAM (256x9) Async Write and Sync Read Ports DO RADDR RDB RBLKB RCLKS RPE PARODD Note: Each RAM block contains a multiplexer (called DMUX) for each output signal, increasing design efficiency. These DMUX cells do not consume any core logic tiles and connect directly to high-speed routing resources between the RAM blocks. They are used when RAM blocks are cascaded and are automatically inserted by the software tools. Figure 1-21 • Example SRAM Block Diagrams Table 1-14 • Memory Block SRAM Interface Signals SRAM Signal Description Bits In/Out WCLKS 1 In Write clock used on synchronization on write side RCLKS 1 In Read clock used on synchronization on read side RADDR 8 In Read address RBLKB 1 In Read block select (active Low) RDB 1 In Read pulse (active Low) WADDR 8 In Write address WBLKB 1 In Write block select (active Low) DI 9 In Input data bits , can be used for parity In WRB 1 In Write pulse (active Low) DO 9 Out Output data bits , can be used for parity Out RPE 1 Out Read parity error (active High) WPE 1 Out Write parity error (active High) PARODD 1 In Selects Odd parity generation/detect when High, Even parity when Low Note: Not all signals shown are used in all modes. v5.8 1-25 ProASICPLUS Flash Family FPGAs DI DI LEVEL LGDEP LEVEL LGDEP DO FIFO (256x9) WRB WBLKB WPE RBLKB PARODD RDB RBLKB EQTH PARODD GEQTH WCLKS FIFO (256x9) WRB WBLKB RPE FULL EMPTY Sync Write and Sync Read Ports RDB DO Sync Write and Async Read Ports DI LEVEL LGDEP WRB WBLKB DO FIFO (256x9) Async Write and Sync Read Ports RBLKB PARODD GEQTH RESET RCLKS RDB EQTH WCLKS RESET DI LEVEL LGDEP WRB WBLKB WPE RPE FULL EMPTY WPE RPE FULL EMPTY EQTH RDB RBLKB GEQTH RESET DO FIFO (256x9) WPE Async Write and Async Read Ports EMPTY EQTH GEQTH PARODD RCLKS RPE FULL RESET Note: Each RAM block contains a multiplexer (called DMUX) for each output signal, increasing design efficiency. These DMUX cells do not consume any core logic tiles and connect directly to high-speed routing resources between the RAM blocks. They are used when RAM blocks are cascaded and are automatically inserted by the software tools. Figure 1-22 • Basic FIFO Block Diagrams Table 1-15 • Memory Block FIFO Interface Signals FIFO Signal Bits In/Out WCLKS 1 In Write clock used for synchronization on write side Description RCLKS 1 In Read clock used for synchronization on read side LEVEL 8 In Direct configuration implements static flag logic RBLKB 1 In Read block select (active Low) RDB 1 In Read pulse (active Low) RESET 1 In Reset for FIFO pointers (active Low) WBLKB 1 In Write block select (active Low) DI 9 In Input data bits , will be generated parity if PARGEN is true WRB 1 In Write pulse (active Low) FULL, EMPTY 2 Out FIFO flags. FULL prevents write and EMPTY prevents read EQTH, GEQTH 2 Out EQTH is true when the FIFO holds the number of words specified by the LEVEL signal. GEQTH is true when the FIFO holds (LEVEL) words or more DO 9 Out Output data bits . will be parity output if PARGEN is true. RPE 1 Out Read parity error (active High) WPE 1 Out LGDEP 3 In Configures DEPTH of the FIFO to 2 (LGDEP+1) PARODD 1 In Parity generation/detect – Even when Low, Odd when High 1 -2 6 Write parity error (active High) v5.8 ProASICPLUS Flash Family FPGAs 9 Word Width 9 9 9 9 9 Word Depth 256 256 9 9 256 9 256 256 256 256 256 256 88 blocks Figure 1-23 • APA1000 Memory Block Architecture Word Width 9 9 Word Depth 9 256 256 256 256 256 256 256 9 9 256 256 256 words x 18 bits, 1 read, 1 write 512 words x 18 bits, 1 read, 1 write 256 1,024 words x 9 bits, 1 read, 1 write Total Memory Blocks Used = 10 Total Memory Bits = 23,040 Figure 1-24 • Example Showing Memory Arrays with Different Widths and Depths Word Width 9 Word Depth 99 9 9 9 Write Port 9 9 Write Port 9 256 256 256 256 256 256 Read Ports 256 256 256 256 256 words x 9 bits, 2 read, 1 write Read Ports 512 words x 9 bits, 4 read, 1 write Total Memory Blocks Used = 10 Total Memory Bits = 6,912 Figure 1-25 • Multi-Port Memory Usage v5.8 1-27 ProASICPLUS Flash Family FPGAs Design Environment The ProASICPLUS family of FPGAs is fully supported by both Actel's Libero® Integrated Design Environment (IDE) and Designer FPGA Development software. Actel Libero IDE is an integrated design manager that seamlessly integrates design tools while guiding the user through the design flow, managing all design and log files, and passing necessary design data among tools. Additionally, Libero IDE allows users to integrate both schematic and HDL synthesis into a single flow and verify the entire design in a single environment (see Actel’s website for more information about Libero IDE). Libero IDE includes Synplify® AE from Synplicity®, ViewDraw® AE from Mentor Graphics®, ModelSim® HDL Simulator from Mentor Graphics, WaveFormer Lite™ AE from SynaptiCAD®, PALACE™ AE Physical Synthesis from Magma, and Designer software from Actel. With the Designer software, a user can lock the design pins before layout while minimally impacting the results of place-and-route. Additionally, Actel’s back-annotation flow is compatible with all the major simulators. Another tool included in the Designer software is the SmartGen macro builder, which easily creates popular and commonly used logic functions for implementation into your schematic or HDL design. PALACE is an effective tool when designing with ProASICPLUS. PALACE AE Physical Synthesis from Magma takes an EDIF netlist and optimizes the performance of ProASICPLUS devices through a physical placement-driven process, ensuring that timing closure is easily achieved. ISP Actel's Designer software is a place-and-route tool that provides a comprehensive suite of back-end support tools for FPGA development. The Designer software includes the following: • Timer – a world-class integrated static timing analyzer and constraints editor that support timing-driven place-and-route • NetlistViewer – a design netlist schematic viewer • ChipPlanner – a graphical floorplanner viewer and editor • SmartPower – allows the designer to quickly estimate the power consumption of a design • PinEditor – a graphical application for editing pin assignments and I/O attributes • I/O Attribute Editor – displays all assigned and unassigned I/O macros and their attributes in a spreadsheet format 1 -2 8 v5.8 Actel's Designer software is compatible with the most popular FPGA design entry and verification tools from EDA vendors, such as Mentor Graphics, Synplicity, Synopsys, and Cadence Design Systems. The Designer software is available for both the Windows and UNIX operating systems. The user can generate *.bit or *.stp programming files from the Designer software and can use these files to program a device. ProASICPLUS devices can be programmed in-system. For more information on ISP of ProASICPLUS devices, refer to the In-System Programming ProASICPLUS Devices and Performing Internal In-System Programming Using Actel’s ProASICPLUS Devices application notes. Prior to being programmed for the first time, the ProASICPLUS device I/Os are in a tristate condition with the pull-up resistor option enabled. ProASICPLUS Flash Family FPGAs Related Documents Application Notes Efficient Use of ProASIC Clock Trees http://www.actel.com/documents/A500K_Clocktree_AN.pdf I/O Features in ProASICPLUS Flash FPGAs http://www.actel.com/documents/APA_LVPECL_AN.pdf Power-Up Behavior of ProASICPLUS Devices http://www.actel.com/documents/APA_PowerUp_AN.pdf ProASICPLUS PLL Dynamic Reconfiguration Using JTAG http://www.actel.com/documents/APA_PLLdynamic_AN.pdf Using ProASICPLUS Clock Conditioning Circuits http://www.actel.com/documents/APA_PLL_AN.pdf In-System Programming ProASICPLUS Devices http://www.actel.com/documents/APA_External_ISP_AN.pdf Performing Internal In-System Programming Using Actel’s ProASICPLUS Devices http://www.actel.com/documents/APA_Microprocessor_AN.pdf ProASICPLUS RAM and FIFO Blocks http://www.actel.com/documents/APA_RAM_FIFO_AN.pdf White Paper Design Security in Nonvolatile Flash and Antifuse FPGAs http://www.actel.com/documents/DesignSecurity_WP.pdf User’s Guide Designer User’s Guide http://www.actel.com/documents/designer_UG.pdf SmartGen Cores Reference Guide http://www.actel.com/documents/gen_refguide_ug.pdf ProASIC and ProASICPLUS Macro Library Guide http://www.actel.com/documents/pa_libguide_UG.pdf Additional Information The following link contains additional information on ProASICPLUS devices. http://www.actel.com/products/proasicplus/default.aspx v5.8 1-29 ProASICPLUS Flash Family FPGAs Package Thermal Characteristics The ProASICPLUS family is available in several package types with a range of pin counts. Actel has selected packages based on high pin count, reliability factors, and superior thermal characteristics. Thermal resistance defines the ability of a package to conduct heat away from the silicon, through the package to the surrounding air. Junction-to-ambient thermal resistance is measured in degrees Celsius/Watt and is represented as Theta ja (Θja). The lower the thermal resistance, the more efficiently a package will dissipate heat. A package’s maximum allowed power (P) is a function of maximum junction temperature (TJ), maximum ambient operating temperature (TA), and junction-to-ambient thermal resistance Θja. Maximum junction temperature is the maximum allowable temperature on the active surface of the IC and is 110° C. P is defined as: T J – TA P = -----------------Θja EQ 1-4 Θja is a function of the rate (in linear feet per minute (lfpm)) of airflow in contact with the package. When the estimated power consumption exceeds the maximum allowed power, other means of cooling, such as increasing the airflow rate, must be used. The maximum power dissipation allowed for a Military temperature device is specified as a function of Θjc. The absolute maximum junction temperature is 150°C. The calculation of the absolute maximum power dissipation allowed for a Military temperature application is illustrated in the following example for a 456-pin PBGA package: Max. junction temp. (°C) – Max. case temp. (°C) 150°C – 125°C Maximum Power Allowed = ------------------------------------------------------------------------------------------------------------------------ = -------------------------------------- = 8.333W 3.0°C/W θ jc (°C/W) EQ 1-5 Table 1-16 • Package Thermal Characteristics θja Pin Count θjc Still Air 1.0 m/s 200 ft./min. 2.5 m/s 500 ft./min. Units 100 14.0 33.5 27.4 25.0 °C/W 144 11.0 33.5 28.0 25.7 °C/W 208 8.0 26.1 22.5 20.8 °C/W PQFP with Heat spreader 208 3.8 16.2 13.3 11.9 °C/W Plastic Ball Grid Array (PBGA) 456 3.0 15.6 12.5 11.6 °C/W Fine Pitch Ball Grid Array (FBGA) 144 3.8 26.9 22.9 21.5 °C/W Fine Pitch Ball Grid Array (FBGA) 256 3.8 26.6 22.8 21.5 °C/W Fine Pitch Ball Grid Array (FBGA)3 484 3.2 18.0 14.7 13.6 °C/W (FBGA)4 484 3.2 20.5 17.0 15.9 °C/W Fine Pitch Ball Grid Array (FBGA) 676 3.2 16.4 13.0 12.0 °C/W Fine Pitch Ball Grid Array (FBGA) 896 2.4 13.6 10.4 9.4 °C/W Fine Pitch Ball Grid Array (FBGA) 1152 1.8 12.0 8.9 7.9 °C/W Ceramic Quad Flat Pack (CQFP) 208 2.0 22.0 19.8 18.0 °C/W Ceramic Quad Flat Pack (CQFP) 352 2.0 17.9 16.1 14.7 °C/W Ceramic Column Grid Array (CCGA/LGA) 624 6.5 8.9 8.5 8.0 °C/W Plastic Packages Thin Quad Flat Pack (TQFP) Thin Quad Flat Pack (TQFP) 1 Plastic Quad Flat Pack (PQFP) 2 Fine Pitch Ball Grid Array Notes: 1. 2. 3. 4. 1 -3 0 Valid for the following devices irrespective of temperature grade: APA075, APA150, and APA300 Valid for the following devices irrespective of temperature grade: APA450, APA600, APA750, and APA1000 Depopulated Array Full array v5.8 ProASICPLUS Flash Family FPGAs Calculating Typical Power Dissipation ProASICPLUS device power is calculated with both a static and an active component. The active component is a function of both the number of tiles utilized and the system speed. Power dissipation can be calculated using the following formula: Total Power Consumption—Ptotal Ptotal = Pdc + Pac where: Pdc = 7 mW for the APA075 8 mW for the APA150 11 mW for the APA300 12 mW for the APA450 12 mW for the APA600 13 mW for the APA750 19 mW for the APA1000 Pdc includes the static components of PVDDP + PVDD + PAVDD Pac = Pclock + Pstorage + Plogic + Poutputs + Pinputs + Ppll + Pmemory Global Clock Contribution—Pclock Pclock, the clock component of power dissipation, is given by the piece-wise model: for R < 15000 the model is: (P1 + (P2*R) - (P7*R2)) * Fs (lightly-loaded clock trees) for R > 15000 the model is: (P10 + P11*R) * Fs (heavily-loaded clock trees) where: P1 = 100 µW/MHz is the basic power consumption of the clock tree per MHz of the clock P2 = 1.3 µW/MHz is the incremental power consumption of the clock tree per storage tile – also per MHz of the clock P7 = 0.00003 µW/MHz is a correction factor for partially-loaded clock trees P10 = 6850 µW/MHz is the basic power consumption of the clock tree per MHz of the clock P11 = 0.4 µW/MHz is the incremental power consumption of the clock tree per storage tile – also per MHz of the clock R = the number of storage tiles clocked by this clock Fs = the clock frequency Storage-Tile Contribution—Pstorage Pstorage, the storage-tile (Register) component of AC power dissipation, is given by Pstorage = P5 * ms * Fs where: P5 = ms Fs = = 1.1 μW/MHz is the average power consumption of a storage tile per MHz of its output toggling rate. The maximum output toggling rate is Fs/2. the number of storage tiles (Register) switching during each Fs cycle the clock frequency v5.8 1-31 ProASICPLUS Flash Family FPGAs Logic-Tile Contribution—Plogic Plogic, the logic-tile component of AC power dissipation, is given by Plogic = P3 * mc * Fs where: P3 = mc Fs = = 1.4 μW/MHz is the average power consumption of a logic tile per MHz of its output toggling rate. The maximum output toggling rate is Fs/2. the number of logic tiles switching during each Fs cycle the clock frequency I/O Output Buffer Contribution—Poutputs Poutputs, the I/O component of AC power dissipation, is given by Poutputs = (P4 + (Cload * VDDP2)) * p * Fp where: P4 = Cload = p = Fp = 326 μW/MHz is the intrinsic power consumption of an output pad normalized per MHz of the output frequency. This is the total I/O current VDDP. the output load the number of outputs the average output frequency I/O Input Buffer's Buffer Contribution—Pinputs The input’s component of AC power dissipation is given by Pinputs = P8 * q * Fq where: P8 = 29 μW/MHz is the intrinsic power consumption of an input pad normalized per MHz of the input frequency. q = the number of inputs Fq = the average input frequency PLL Contribution—Ppll Ppll = P9 * Npll where: P9 = 7.5 mW. This value has been estimated at maximum PLL clock frequency. NPll = number of PLLs used RAM Contribution—Pmemory Finally, Pmemory, the memory component of AC power consumption, is given by Pmemory = P6 * Nmemory * Fmemory * Ememory where: 1 -3 2 P6 Nmemory = = Fmemory Ememory = = 175 μW/MHz is the average power consumption of a memory block per MHz of the clock the number of RAM/FIFO blocks (1 block = 256 words * 9 bits) the clock frequency of the memory the average number of active blocks divided by the total number of blocks (N) of the memory. • Typical values for Ememory would be 1/4 for a 1k x 8,9,16, 32 memory and 1/16 for a 4kx8, 9, 16, and 32 memory configuration • In addition, an application-dependent component to Ememory can be considered. For example, for a 1kx8 memory configuration using only 1 cycle out of 2, Ememory = 1/4*1/2 = 1/8 v5.8 ProASICPLUS Flash Family FPGAs The following is an APA750 example using a shift register design with 13,440 storage tiles (Register) and 0 logic tiles. This design has one clock at 10 MHz, and 24 outputs toggling at 5 MHz. We then calculate the various components as follows: Pclock Fs = 10 MHz R = 13,440 Pclock = (P1 + (P2*R) - (P7*R2)) * Fs = 121.5 mW => Pstorage ms => = 13,440 (in a shift register 100% of storage tiles are toggling at each clock cycle and Fs = 10 MHz) Pstorage = P5 * ms * Fs = 147.8 mW Plogic mc => = 0 (no logic tiles in this shift register) Plogic = 0 mW Poutputs => Cload = 40 pF VDDP = 3.3 V p = 24 Fp = 5 MHz Poutputs = (P4 + (Cload * VDDP2)) * p * Fp = 91.4 mW Pinputs => q = 1 Fq = 10 MHz Pinputs = P8 * q * Fq = 0.3 mW Pmemory Nmemory => = 0 (no RAM/FIFO blocks in this shift register) Pmemory = 0 mW Pac => 361 mW Ptotal Pdc + Pac = 374 mW (typical) v5.8 1-33 ProASICPLUS Flash Family FPGAs Operating Conditions Standard and –F parts are the same unless otherwise noted. All –F parts are only available as commercial. Table 1-17 • Absolute Maximum Ratings* Parameter Condition Minimum Maximum Units Supply Voltage Core (VDD) –0.3 3.0 V Supply Voltage I/O Ring (VDDP) –0.3 4.0 V DC Input Voltage –0.3 VDDP + 0.3 V PCI DC Input Voltage –1.0 VDDP + 1.0 V PCI DC Input Clamp Current (absolute) VIN < –1 or VIN = VDDP + 1 V LVPECL Input Voltage GND 10 mA –0.3 VDDP + 0.5 V 0 0 V Note: *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. Devices should not be operated outside the Recommended Operating Conditions. Table 1-18 • Programming, Storage, and Operating Limits Storage Temperature Product Grade Commercial Operating Programming Cycles (min.) Program Retention (min.) Min. Max. TJ Max. Junction Temperature 500 20 years –55°C 110°C 110°C Industrial 500 20 years –55°C 110°C 110°C Military 100 Refer to Table 1-19 on page 1-35 –65°C 150°C 150°C MIL-STD-883 100 Refer to Table 1-19 on page 1-35 –65°C 150°C 150°C Performance Retention For devices operated and stored at 110°C or less, the performance retention period is 20 years after programming. For devices operated and stored at temperatures greater than 110°C, refer to Table 1-19 on page 1-35 to determine the performance retention period. Actel does not guarantee performance if the performance retention period is exceeded. Designers can determine the performance retention period from the following table. Evaluate the percentage of time spent at the highest temperature, then determine the next highest temperature to which the device will be exposed. In Table 1-19 on page 1-35, find the temperature profile that most closely matches the application. 1 -3 4 v5.8 Example – the ambient temperature of a system cycles between 100°C (25% of the time) and 50°C (75% of the time). No forced ventilation cooling system is in use. An APA600-PQ208M FPGA operates in the system, dissipating 1 W. The package thermal resistance (junction-to-ambient) in still air Θja is 20°C/W, indicating that the junction temperature of the FPGA will be 120°C (25% of the time) and 70°C (75% of the time). The entry in Table 1-19 on page 1-35, which most closely matches the application, is 25% at 125°C with 75% at 110°C. Performance retention in this example is at least 16.0 years. Note that exceeding the stated retention period may result in a performance degradation in the FPGA below the worst-case performance indicated in the Actel Timer. To ensure that performance does not degrade below the worst-case values in the Actel Timer, the FPGA must be reprogrammed within the performance retention period. In addition, note that performance retention is independent of whether or not the FPGA is operating. The retention period of a device in storage at a given temperature will be the same as the retention period of a device operating at that junction temperature. ProASICPLUS Flash Family FPGAs Table 1-19 • Military Temperature Grade Product Performance Retention Minimum Time at TJ 110°C or below Minimum Time at TJ 125°C or below Minimum Time at TJ 135°C or below Minimum Time at TJ 150°C or below 100% Minimum Performance Retention (Years) 20.0 90% 10% 18.2 75% 25% 16 90% 50% 10% 15.4 50% 13.3 90% 10% 75% 25% 11.4 100% 90% 50% 75% 10 10% 9.1 50% 8 25% 8 90% 75% 50% 11.8 10% 7.7 25% 7.3 50% 75% 6.7 25% 100% 90% 5.7 5 10% 4.5 50% 4.4 50% 4 75% 25% 4 50% 50% 3.3 100% 2.5 50% 50% v5.8 1-35 ProASICPLUS Flash Family FPGAs Table 1-20 • Recommended Maximum Operating Conditions Programming and PLL Supplies Commercial/Industrial/Military/MIL-STD-883 Parameter VPP Condition Maximum Units 15.8 16.5 V 0 16.5 V –13.8 –13.2 V –13.8 During Programming Normal Operation VPN Minimum 1 During Programming 2 0.5 V IPP During Programming 25 mA IPN During Programming 10 mA Normal Operation AVDD VDD VDD V AGND GND GND V Notes: 1. Please refer to the "VPP Programming Supply Pin" section on page 1-77 for more information. 2. Please refer to the "VPN Programming Supply Pin" section on page 1-77 for more information. Table 1-21 • Recommended Operating Conditions Limits Parameter Symbol Commercial Industrial Military/MIL-STD-883 DC Supply Voltage (2.5 V I/Os) VDD and VDDP 2.5 V ± 0.2 V 2.5 V ± 0.2 V 2.5 V ± 0.2 V DC Supply Voltage (3.3 V I/Os) VDDP VDD 3.3 V ± 0.3 V 2.5 V ± 0.2 V 3.3 V ± 0.3 V 2.5 V ± 0.2 V 3.3 V ± 0.3 V 2.5 V ± 0.2 V Operating Ambient Temperature Range TA, TC 0°C to 70°C –40°C to 85°C –55°C (TA) to 125°C (TC) TJ 110°C 110°C 150°C Maximum Operating Junction Temperature Note: For I/O long-term reliability, external pull-up resistors cannot be used to increase output voltage above VDDP. 1 -3 6 v5.8 ProASICPLUS Flash Family FPGAs Table 1-22 • DC Electrical Specifications (VDDP = 2.5 V ±0.2V) Commercial/Industrial/ Military/MIL-STD-8831, 2 Symbol Parameter VOH Output High Voltage High Drive (OB25LPH) Low Drive (OB25LPL) VOL Conditions Min. IOH = –6 mA IOH = –12 mA IOH = –24 mA 2.1 2.0 1.7 IOH = –3 mA IOH = –6 mA IOH = –8 mA 2.1 1.9 1.7 Typ. Max. Units V Output Low Voltage High Drive (OB25LPH) Low Drive (OB25LPL) IOL = 8 mA IOL = 15 mA IOL = 24 mA 0.2 0.4 0.7 IOL = 4 mA IOL = 8 mA IOL = 15 mA 0.2 0.4 0.7 V VIH6 Input High Voltage 1.7 VDDP + 0.3 V VIL7 Input Low Voltage –0.3 0.7 V 6 56 kΩ 0.45 V RWEAKPULLUP Weak Pull-up Resistance (OTB25LPU) VIN ≥ 1.25 V HYST Input Hysteresis Schmitt See Table 1-4 on page 1-9 IIN Input Current with pull up (VIN = GND) –240 – 20 µA without pull up (VIN = GND or VDD) –10 10 µA IDDQ IDDQ IDDQ GND4 Quiescent Supply Current (standby) Commercial VIN = Quiescent Supply Current (standby) Industrial VIN = GND4 or VDD Quiescent Supply Current (standby) Military/MIL-STD-883 VIN = GND4 or VDD or VDD Tristate Output Leakage Current VOH = GND or VDD IOZ 0.3 0.35 Std. 5.0 15 mA –F3 5.0 25 mA 5.0 20 mA 5.0 25 mA Std. Std. Std. –10 10 µA –F3, 5 –10 100 µA Notes: 1. 2. 3. 4. 5. 6. 7. All process conditions. Commercial/Industrial: Junction Temperature: –40 to +110°C. All process conditions. Military: Junction Temperature: –55 to +150°C. All –F parts are available only as commercial. No pull-up resistor. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to -1.0V for a limited time of no larger than 10% of the duty cycle. v5.8 1-37 ProASICPLUS Flash Family FPGAs Table 1-22 • DC Electrical Specifications (VDDP = 2.5 V ±0.2V) (Continued) Commercial/Industrial/ Military/MIL-STD-8831, 2 Symbol Parameter IOSH Output Short Circuit Current High High Drive (OB25LPH) VIN = VSS VIN = VSS Low Drive (OB25LPL) IOSL Min. Conditions Typ. Max. Units mA –120 –100 mA Output Short Circuit Current Low High Drive (OB25LPH) VIN = VDDP VIN = VDDP Low Drive (OB25LPL) 100 30 CI/O I/O Pad Capacitance 10 pF CCLK Clock Input Pad Capacitance 10 pF Notes: 1. 2. 3. 4. 5. 6. 7. All process conditions. Commercial/Industrial: Junction Temperature: –40 to +110°C. All process conditions. Military: Junction Temperature: –55 to +150°C. All –F parts are available only as commercial. No pull-up resistor. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to -1.0V for a limited time of no larger than 10% of the duty cycle. 1 -3 8 v5.8 ProASICPLUS Flash Family FPGAs Table 1-23 • DC Electrical Specifications (VDDP = 3.3 V ±0.3 V and VDD = 2.5 V ±0.2 V) Applies to Commercial and Industrial Temperature Only Commercial/Industrial1 Symbol Parameter VOH Output High Voltage 3.3 V I/O, High Drive (OB33P) 3.3 V I/O, Low Drive (OB33L) Output Low Voltage 3.3 V I/O, High Drive (OB33P) VOL Conditions Min. IOH = –14 mA IOH = –24 mA 0.9∗VDDP 2.4 IOH = –6 mA IOH = –12 mA 0.9∗VDDP 2.4 Typ. Max. V IOL = 15 mA IOL = 20 mA IOL = 28 mA 0.1VDDP 0.4 0.7 IOL = 7 mA IOL = 10 mA IOL = 15 mA 0.1VDDP 0.4 0.7 3.3 V I/O, Low Drive (OB33L) VIH5 VIL6 1.6 2 1.7 VDDP + 0.3 VDDP + 0.3 VDDP + 0.3 Input Low Voltage 3.3 V Schmitt Trigger Inputs 3.3 V LVTTL/LVCMOS 2.5 V Mode –0.3 –0.3 –0.3 0.8 0.8 0.7 V Resistance VIN ≥ 1.5 V 7 43 kΩ Resistance VIN ≥ 1.5 V 7 43 kΩ with pull up (VIN = GND) –300 –40 µA without pull up (VIN = GND or VDD) –10 10 µA RWEAKPULLUP Weak Pull-up (IOB25U) Input Current IDDQ IDDQ IDDQ V Input High Voltage 3.3 V Schmitt Trigger Inputs 3.3 V LVTTL/LVCMOS 2.5 V Mode Pull-up RWEAKPULLUP Weak (IOB33U) IIN Units GND3 Quiescent Supply Current (standby) Commercial VIN = Quiescent Supply Current (standby) Industrial VIN = GND3 or VDD Quiescent Supply Current (standby) Military VIN = GND3 or VDD V Std. 5.0 15 mA –F2 5.0 25 mA Std. 5.0 20 mA Std. 5.0 25 mA or VDD Notes: 1. 2. 3. 4. 5. 6. All process conditions. Commercial/Industrial: Junction Temperature: –40 to +110°C. All –F parts are only available as commercial. No pull-up resistor required. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0 V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to –1.0 V for a limited time of no larger than 10% of the duty cycle. v5.8 1-39 ProASICPLUS Flash Family FPGAs Table 1-23 • DC Electrical Specifications (VDDP = 3.3 V ±0.3 V and VDD = 2.5 V ±0.2 V) (Continued) Applies to Commercial and Industrial Temperature Only Commercial/Industrial1 Symbol Parameter IOZ Tristate Current IOSH Output Conditions Min. Leakage VOH = GND or VDD Output Short Circuit Current High 3.3 V High Drive (OB33P) VIN = GND 3.3 V Low Drive (OB33L) VIN = GND Typ. Max. Units Std. –10 10 µA –F2, 4 –10 100 µA –200 –100 Output Short Circuit Current Low 3.3 V High Drive VIN = VDD VIN = VDD 3.3 V Low Drive 200 100 CI/O I/O Pad Capacitance 10 pF CCLK Clock Input Pad Capacitance 10 pF IOSL Notes: 1. 2. 3. 4. 5. 6. 1 -4 0 All process conditions. Commercial/Industrial: Junction Temperature: –40 to +110°C. All –F parts are only available as commercial. No pull-up resistor required. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0 V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to –1.0 V for a limited time of no larger than 10% of the duty cycle. v5.8 ProASICPLUS Flash Family FPGAs Table 1-24 • DC Electrical Specifications (VDDP = 3.3 V ±0.3 V and VDD = 2.5 V ±0.2 V) Applies to Military Temperature and MIL-STD-883B Temperature Only Military/MIL-STD-883B1 Symbol Parameter VOH Output High Voltage 3.3 V I/O, High Drive, High Slew IOH = –8 mA (OB33PH) IOH = –16 mA VOL VIL5 3.3 V I/O, Low Drive , High/ Normal/Low Slew (OB33LH/ OB33LN/OB33LL) 0.9∗VDDP 2.4 Max. Units IOH = –3 mA IOH = –8 mA V Output Low Voltage 3.3 V I/O, High Drive, High Slew IOL = 12 mA IOL = 17 mA (OB33PH) IOL = 28 mA 0.1VDDP 0.4 0.7 3.3V I/O, High Drive, Normal/ IOL = 4 mA IOL = 6 mA Low Slew (OB33PN/OB33PL)) IOL = 13 mA 0.1VDDP 0.4 0.7 IOL = 4 mA IOL = 6 mA IOL = 13 mA 0.1VDDP 0.4 0.7 V Input High Voltage 3.3 V Schmitt Trigger Inputs 3.3 V LVTTL/LVCMOS 2.5 V Mode 1.6 2 1.7 VDDP + 0.3 VDDP + 0.3 VDDP + 0.3 Input Low Voltage 3.3 V Schmitt Trigger Inputs 3.3 V LVTTL/LVCMOS 2.5 V Mode –0.3 –0.3 –0.3 0.7 0.8 0.7 V VIN ≥ 1.5 V 7 43 kΩ VIN ≥ 1.5 V 7 43 kΩ with pull up (VIN = GND) –300 –40 µA without pull up (VIN = GND or VDD) –10 10 µA RWEAKPULLUP Weak Pull-up Resistance (IOB25U) Input Current IDDQ Typ. 0.9∗VDDP 2.4 0.9∗VDDP 2.4 RWEAKPULLUP Weak Pull-up Resistance (IOB33U) IIN Min. 3.3V I/O, High Drive, Normal/ IOH = –3mA Low Slew (OB33PN/OB33PL) IOH = –8mA 3.3 V I/O, Low Drive, High/ Normal/Low Slew (OB33LH/ OB33LN/OB33LL) VIH4 Conditions Quiescent Supply Current (standby) Commercial 2 VIN = GND or VDD V Std. 5.0 15 mA –F 5.0 25 mA Notes: 1. 2. 3. 4. 5. All process conditions. Military Temperature / MIL-STD-883 Class B: Junction Temperature: –55 to +125°C. No pull-up resistor required. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0 V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to –1.0 V for a limited time of no larger than 10% of the duty cycle. v5.8 1-41 ProASICPLUS Flash Family FPGAs Table 1-24 • DC Electrical Specifications (VDDP = 3.3 V ±0.3 V and VDD = 2.5 V ±0.2 V) (Continued) Applies to Military Temperature and MIL-STD-883B Temperature Only Military/MIL-STD-883B1 Symbol IDDQ IDDQ Parameter Quiescent Supply Current (standby) Industrial Quiescent Supply Current (standby) Military Tristate Current IOZ IOSH Conditions Output Min. Typ. Max. Units Std. 5.0 20 mA Std. 5.0 25 mA 2 VIN = GND or VDD 2 VIN = GND or VDD Leakage VOH = GND or VDD Std. –10 10 µA 3 –10 100 µA –F Output Short Circuit Current High 3.3 V High Drive (OB33P) VIN = GND 3.3 V Low Drive (OB33L) VIN = GND –200 –100 Output Short Circuit Current Low 3.3 V High Drive VIN = VDD VIN = VDD 3.3 V Low Drive 200 100 CI/O I/O Pad Capacitance 10 pF CCLK Clock Input Pad Capacitance 10 pF IOSL Notes: 1. 2. 3. 4. 5. 1 -4 2 All process conditions. Military Temperature / MIL-STD-883 Class B: Junction Temperature: –55 to +125°C. No pull-up resistor required. This will not exceed 2 mA total per device. During transitions, the input signal may overshoot to VDDP +1.0 V for a limited time of no larger than 10% of the duty cycle. During transitions, the input signal may undershoot to –1.0 V for a limited time of no larger than 10% of the duty cycle. v5.8 ProASICPLUS Flash Family FPGAs Table 1-25 • DC Specifications (3.3 V PCI Operation)1 Commercial/ Industrial2,3 Symbol Parameter VDD Condition Military/MIL-STD- 8832,3 Min. Max. Min. Max. Units Supply Voltage for Core 2.3 2.7 2.3 2.7 V VDDP Supply Voltage for I/O Ring 3.0 3.6 3.0 3.6 V VIH Input High Voltage 0.5VDDP VDDP + 0.5 V VIL Input Low Voltage –0.5 0.3VDDP V 0.5VDDP VDDP + 0.5 –0.5 4 IIPU Input Pull-up Voltage IIL Input Leakage Current5 0.3VDDP 0.7VDDP 0 < VIN < VDDP Std. 3, 6 –F VOH Output High Voltage IOUT = –500 µA VOL Output Low Voltage IOUT = 1500 µA CIN Input Pin Capacitance (except CLK) CCLK CLK Pin Capacitance 0.7VDDP –10 10 –10 100 0.9VDDP 5 –50 V 50 μA μA 0.9VDDP V 0.1VDDP 0.1VDDP V 10 10 pF 12 pF 12 5 Notes: 1. 2. 3. 4. For PCI operation, use GL33, OTB33PH, OB33PH, IOB33PH, IB33, or IB33S macro library cell only. All process conditions. Junction Temperature: –40 to +110°C for Commercial and Industrial devices and –55 to +125°C for Military. All –F parts are available as commercial only. This specification is guaranteed by design. It is the minimum voltage to which pull-up resistors are calculated to pull a floated network. Designers with applications sensitive to static power utilization should ensure that the input buffer is conducting minimum current at this input voltage. 5. Input leakage currents include hi-Z output leakage for all bidirectional buffers with tristate outputs. 6. The sum of the leakage currents for all inputs shall not exceed 2mA per device. v5.8 1-43 ProASICPLUS Flash Family FPGAs Table 1-26 • AC Specifications (3.3 V PCI Revision 2.2 Operation) Commercial/Industrial/Military/MIL-STD- 883 Symbol Parameter IOH(AC) IOL(AC) Switching Current High Condition Min. 0 < VOUT ≤ 0.3VDDP* 0.3VDDP ≤ VOUT < 0.9VDDP* 0.7VDDP < VOUT < VDDP* (Test Point) VOUT = 0.7VDDP* Switching Current Low VDDP > VOUT ≥ mA (–17.1 + (VDDP – VOUT)) mA See equation C – page 124 of the PCI Specification document rev. 2.2 –32VDDP 1 mA (26.7VOUT) mA See equation D – page 124 of the PCI Specification document rev. 2.2 (Test Point) VOUT = 0.18VDDP ICL Low Clamp Current –3 < VIN ≤ –1 ICH High Clamp Current VDDP + 4 > VIN ≥ VDDP + 1 slewF Output Fall Slew Rate 38VDDP mA –25 + (VIN + 1)/0.015 mA 25 + (VIN – VDDP – 1)/0.015 mA 0.2VDDP to 0.6VDDP load* 1 4 V/ns 0.6VDDP to 0.2VDDP load* 1 4 V/ns Note: * Refer to the PCI Specification document rev. 2.2. Pad Loading Applicable to the Rising Edge PCI pin 1/2 in. max output buffer 10 pF 1kΩ Pad Loading Applicable to the Falling Edge PCI pin output buffer 1 -4 4 mA 16VDDP 0.18VDDP > VOUT > 0* Output Rise Slew Rate Units –12VDDP 0.6VDDP* 0.6VDDP > VOUT > 0.1VDDP slewR Max. 1kΩ 10 pF v5.8 ProASICPLUS Flash Family FPGAs Tristate Buffer Delays EN A PAD OTBx A 50% 50% VOH PAD VOL EN EN 50% 50% tDLH 35pF tDHL 50% 50% VDDP 50% PAD VOL tENZL 50% 50% VOH PAD GND 10% 90% 50% tENZH Figure 1-26 • Tristate Buffer Delays Table 1-27 • Worst-Case Commercial Conditions VDDP = 3.0 V, VDD = 2.3 V, 35 pF load, TJ = 70°C Max tDLH1 Macro Type Description Max tDHL2 Max tENZH3 Max tENZL4 Std. –F Std. –F Std. –F Units OTB33PH 3.3 V, PCI Output Current, High Slew Rate 2.0 2.4 2.2 2.6 2.2 2.6 –F Std. 2.0 2.4 ns OTB33PN 3.3 V, High Output Current, Nominal Slew Rate 2.2 2.6 2.9 3.5 2.4 2.9 2.1 2.5 ns OTB33PL 3.3 V, High Output Current, Low Slew Rate 2.5 3.0 3.2 3.9 2.7 3.3 2.8 3.4 ns OTB33LH 3.3 V, Low Output Current, High Slew Rate 2.6 3.1 4.0 4.8 2.8 3.4 3.0 3.6 ns OTB33LN 3.3 V, Low Output Current, Nominal Slew Rate 2.9 3.5 4.3 5.2 3.2 3.8 4.1 4.9 ns OTB33LL 3.3 V, Low Output Current, Low Slew Rate 3.0 3.6 5.6 6.7 3.3 3.9 5.5 6.6 ns Notes: 1. 2. 3. 4. 5. tDLH=Data-to-Pad High tDHL=Data-to-Pad Low tENZH=Enable-to-Pad, Z to High tENZL = Enable-to-Pad, Z to Low All –F parts are only available as commercial. Table 1-28 • Worst-Case Commercial Conditions VDDP = 2.3 V, VDD = 2.3 V, 35 pF load, TJ = 70°C Max tDLH1 Macro Type OTB25LPHH Description 2.5 V, Low Power, High Output Current, High Slew Rate5 5 Max tDHL2 Max tENZH3 Max tENZL4 Std. –F Std. –F Std. –F Units 2.0 2.4 2.1 2.5 2.3 2.7 –F Std. 2.0 2.4 ns 2.4 2.9 3.0 3.6 2.7 3.2 2.1 2.5 ns OTB25LPHL 2.5 V, Low Power, High Output Current, Low Slew Rate5 2.9 3.5 3.2 3.8 3.1 3.8 2.7 3.2 ns OTB25LPLH 2.5 V, Low Power, Low Output Current, High Slew Rate5 2.7 3.3 4.6 5.5 3.0 3.6 2.6 3.1 ns OTB25LPHN 2.5 V, Low Power, High Output Current, Nominal Slew Rate Notes: 1. 2. 3. 4. 5. 6. tDLH=Data-to-Pad High tDHL=Data-to-Pad Low tENZH=Enable-to-Pad, Z to High tENZL = Enable-to-Pad, Z to Low Low power I/O work with VDDP=2.5 V ±10% only. VDDP=2.3 V for delays. All –F parts are only available as commercial. v5.8 1-45 ProASICPLUS Flash Family FPGAs Table 1-28 • Worst-Case Commercial Conditions VDDP = 2.3 V, VDD = 2.3 V, 35 pF load, TJ = 70°C Max tDLH1 OTB25LPLL Max tENZH3 Max tENZL4 Description Std. –F Std. –F Std. –F Units 2.5 V, Low Power, Low Output Current, Nominal Slew Rate5 3.5 4.2 4.2 5.1 3.8 4.5 3.8 4.6 ns 4.0 4.8 5.3 6.4 4.2 5.1 5.1 6.1 ns Macro Type OTB25LPLN Max tDHL2 2.5 V, Low Power, Low Output Current, Low Slew Rate5 –F Std. Notes: 1. 2. 3. 4. 5. 6. tDLH=Data-to-Pad High tDHL=Data-to-Pad Low tENZH=Enable-to-Pad, Z to High tENZL = Enable-to-Pad, Z to Low Low power I/O work with VDDP=2.5 V ±10% only. VDDP=2.3 V for delays. All –F parts are only available as commercial. Table 1-29 • Worst-Case Military Conditions VDDP = 3.0 V, VDD = 2.3 V, 35 pF load, TJ = 125°C for Military/MIL-STD-883 Max tDLH1 Max tDHL2 Max tENZH3 Max tENZL4 Std. Std. Std. Std. Units Macro Type Description OTB33PH 3.3 V, PCI Output Current, High Slew Rate 2.2 2.4 2.3 2.1 ns OTB33PN 3.3 V, High Output Current, Nominal Slew Rate 2.4 3.2 2.7 2.3 ns OTB33PL 3.3 V, High Output Current, Low Slew Rate 2.7 3.5 2.9 3.0 ns OTB33LH 3.3 V, Low Output Current, High Slew Rate 2.7 4.3 3.0 3.1 ns OTB33LN 3.3 V, Low Output Current, Nominal Slew Rate 3.3 4.7 3.4 4.4 ns OTB33LL 3.3 V, Low Output Current, Low Slew Rate 3.2 6.0 3.5 5.9 ns Max tDLH1 Max tDHL2 Max tENZH3 Max tENZL4 Notes: 1. 2. 3. 4. tDLH=Data-to-Pad High tDHL=Data-to-Pad Low tENZH=Enable-to-Pad, Z to High tENZL = Enable-to-Pad, Z to Low Table 1-30 • Worst-Case Military Conditions VDDP = 2.3 V, VDD = 2.3 V, 35 pF load, TJ = 125°C for Military/MIL-STD-883 Macro Type Description Std. Std. Std. Std. Units OTB25LPHH 2.5 V, Low Power, High Output Current, High Slew Rate5 2.3 2.3 2.4 2.1 ns OTB25LPHN 2.5 V, Low Power, High Output Current, Nominal Slew Rate5 2.7 3.2 2.8 2.1 ns OTB25LPHL 2.5 V, Low Power, High Output Current, Low Slew Rate5 3.2 3.5 3.3 2.8 ns OTB25LPLH 2.5 V, Low Power, Low Output Current, High Slew Rate5 3.0 5.0 3.2 2.8 ns 3.7 4.5 4.1 4.1 ns 4.4 5.8 4.4 5.4 ns OTB25LPLN OTB25LPLL 2.5 V, Low Power, Low Output Current, Nominal Slew Rate 2.5 V, Low Power, Low Output Current, Low Slew Rate Notes: 1. 2. 3. 4. 5. 1 -4 6 tDLH=Data-to-Pad High tDHL=Data-to-Pad Low tENZH=Enable-to-Pad, Z to High tENZL = Enable-to-Pad, Z to Low Low power I/O work with VDDP=2.5V ±10% only. VDDP=2.3V for delays. v5.8 5 5 ProASICPLUS Flash Family FPGAs Output Buffer Delays A 50% 50% VOH 50% PAD 50% VOL tDLH tDHL PAD A 35pF OBx Figure 1-27 • Output Buffer Delays Table 1-31 • Worst-Case Commercial Conditions VDDP = 3.0 V, VDD = 2.3 V, 35 pF load, TJ = 70°C Max tDLH1 Macro Type Description Max tDHL2 Std. –F Std. –F Units OB33PH 3.3 V, PCI Output Current, High Slew Rate 2.0 2.4 2.2 2.6 ns OB33PN 3.3 V, High Output Current, Nominal Slew Rate 2.2 2.6 2.9 3.5 ns OB33PL 3.3 V, High Output Current, Low Slew Rate 2.5 3.0 3.2 3.9 ns OB33LH 3.3 V, Low Output Current, High Slew Rate 2.6 3.1 4.0 4.8 ns OB33LN 3.3 V, Low Output Current, Nominal Slew Rate 2.9 3.5 4.3 5.2 ns OB33LL 3.3 V, Low Output Current, Low Slew Rate 3.0 3.6 5.6 6.7 ns Notes: 1. tDLH = Data-to-Pad High 2. tDHL = Data-to-Pad Low 3. All –F parts are only available as commercial. Table 1-32 • Worst-Case Commercial Conditions VDDP = 2.3 V, VDD = 2.3 V, 35 pF load, TJ = 70°C Max tDLH1 Macro Type Description Rate3 OB25LPHH 2.5 V, Low Power, High Output Current, High Slew OB25LPHN 2.5 V, Low Power, High Output Current, Nominal Slew Rate3 OB25LPHL OB25LPLH 2.5 V, Low Power, High Output Current, Low Slew Rate 2.5 V, Low Power, Low Output Current, High Slew 3 Rate3 3 Max tDHL2 Std. –F Std. –F Units 2.0 2.4 2.1 2.6 ns 2.4 2.9 3.0 3.6 ns 2.9 3.5 3.2 3.8 ns 2.7 3.3 4.6 5.5 ns OB25LPLN 2.5 V, Low Power, Low Output Current, Nominal Slew Rate 3.5 4.2 4.2 5.1 ns OB25LPLL 2.5 V, Low Power, Low Output Current, Low Slew Rate3 4.0 4.8 5.3 6.4 ns Notes: 1. 2. 3. 4. tDLH = Data-to-Pad High tDHL = Data-to-Pad Low Low-power I/Os work with VDDP=2.5 V ±10% only. VDDP=2.3 V for delays. All –F parts are only available as commercial. v5.8 1-47 ProASICPLUS Flash Family FPGAs Table 1-33 • Worst-Case Military Conditions VDDP = 3.0V, VDD = 2.3V, 35 pF load, TJ = 125°C for Military/MIL-STD-883 Max. tDLH1 Max. tDHL2 Std. Std. Units Macro Type Description OB33PH 3.3V, PCI Output Current, High Slew Rate 2.1 2.3 ns OB33PN 3.3V, High Output Current, Nominal Slew Rate 2.5 3.2 ns OB33PL 3.3V, High Output Current, Low Slew Rate 2.7 3.5 ns OB33LH 3.3V, Low Output Current, High Slew Rate 2.7 4.3 ns OB33LN 3.3V, Low Output Current, Nominal Slew Rate 3.3 4.7 ns OB33LL 3.3V, Low Output Current, Low Slew Rate 3.3 6.1 ns Max. tDLH1 Max. tDHL2 Std. Std. Units 2.3 2.4 ns 2.7 3.3 ns 3.2 3.5 ns 3.0 5.0 ns 3.9 4.6 ns 4.3 5.7 ns Notes: 1. tDLH = Data-to-Pad High 2. tDHL = Data-to-Pad Low Table 1-34 • Worst-Case Military Conditions VDDP = 2.3 V, VDD = 2.3V, 35 pF load, TJ = 125°C for Military/MIL-STD-883 Macro Type OB25LPHH OB25LPHN Description 2.5V, Low Power, High Output Current, High Slew Rate 3 2.5V, Low Power, High Output Current, Nominal Slew Rate Rate3 OB25LPHL 2.5V, Low Power, High Output Current, Low Slew OB25LPLH 2.5V, Low Power, Low Output Current, High Slew Rate3 OB25LPLN OB25LPLL 2.5V, Low Power, Low Output Current, Nominal Slew Rate 2.5V, Low Power, Low Output Current, Low Slew Rate3 Notes: 1. tDLH = Data-to-Pad High 2. tDHL = Data-to-Pad Low 3. Low power I/O work with VDDP=2.5V ±10% only. VDDP=2.3V for delays. 1 -4 8 v5.8 3 3 ProASICPLUS Flash Family FPGAs Input Buffer Delays VDDP PAD Y PAD Y GND IBx 0V 50% 50% VDD 50% tINYH 50% tIN YL Figure 1-28 • Input Buffer Delays Table 1-35 • Worst-Case Commercial Conditions VDDP = 3.0 V, VDD = 2.3 V, TJ = 70°C Macro Type Description Levels3, IB33 3.3 V, CMOS Input IB33S 3.3 V, CMOS Input Levels3, No Pull-up Resistor, Schmitt Trigger No Pull-up Resistor Max. tINYH1 Max. tINYL2 Std. –F Std. –F Units 0.4 0.5 0.6 0.7 ns 0.6 0.7 0.8 0.9 ns Notes: 1. 2. 3. 4. 5. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3 V for delays. All –F parts are only available as commercial. Table 1-36 • Worst-Case Commercial Conditions VDDP = 2.3 V, VDD = 2.3 V, TJ = 70°C Macro Type IB25LP IB25LPS Description 2.5 V, CMOS Input Levels3, Low Power 3, 2.5 V, CMOS Input Levels Low Power, Schmitt Trigger Max. tINYH1 Max. tINYL2 Std. –F Std. –F Units 0.9 1.1 0.6 0.8 ns 0.7 0.9 0.9 1.1 ns Notes: 1. 2. 3. 4. 5. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3 V for delays. All –F parts are only available as commercial. v5.8 1-49 ProASICPLUS Flash Family FPGAs Table 1-37 • Worst-Case Military Conditions VDDP = 3.0V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Macro Type Description Levels3 IB33 3.3V, CMOS Input IB33S 3.3V, CMOS Input Levels3, No Pull-up Resistor, Schmitt Trigger , No Pull-up Resistor Max. tINYH1 Max. tINYL2 Std. Std. Units 0.5 0.6 ns 0.6 0.8 ns Max. tINYH1 Max. tINYL2 Std. Std. Units 0.9 0.7 ns 0.8 1.0 ns Notes: 1. 2. 3. 4. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3V for delays. Table 1-38 • Worst-Case Military Conditions VDDP = 2.3V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Macro Type IB25LP IB25LPS Description 3, 2.5V, CMOS Input Levels Low Power 2.5V, CMOS Input Levels3, Low Power, Schmitt Trigger Notes: 1. 2. 3. 4. 1 -5 0 tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3V for delays. v5.8 ProASICPLUS Flash Family FPGAs Global Input Buffer Delays Table 1-39 • Worst-Case Commercial Conditions VDDP = 3.0 V, VDD = 2.3 V, TJ = 70°C Max. tINYH1 Macro Type GL33 Description 4 3 Units –F Std. 1.0 1.2 1.1 1.3 ns Std. 3.3 V, CMOS Input Levels4, No Pull-up Resistor 3 Max. tINYL2 –F GL33S 3.3 V, CMOS Input Levels , No Pull-up Resistor, Schmitt Trigger 1.0 1.2 1.1 1.3 ns PECL PPECL Input Levels 1.0 1.2 1.1 1.3 ns Notes: 1. 2. 3. 4. 5. 6. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low Applies to Military ProASICPLUS devices. LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3 V for delays. All –F parts are only available as commercial. Table 1-40 • Worst-Case Commercial Conditions VDDP = 2.3 V, VDD = 2.3 V, TJ = 70°C Max. tINYH1 Macro Type Description Std. 4, 3 Max. tINYL2 –F Std.3 –F Units GL25LP 2.5 V, CMOS Input Levels Low Power 1.1 1.2 1.0 1.3 ns GL25LPS 2.5 V, CMOS Input Levels4, Low Power, Schmitt Trigger 1.3 1.6 1.0 1.1 ns Notes: 1. 2. 3. 4. 5. 6. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low Applies to Military ProASICPLUS devices. LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3 V for delays. All –F parts are only available as commercial. v5.8 1-51 ProASICPLUS Flash Family FPGAs Table 1-41 • Worst-Case Military Conditions VDDP = 3.0V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Macro Type Description 3 Max. tINYH1 Max. tINYL2 Std. Std. GL33 3.3V, CMOS Input Levels , No Pull-up Resistor 1.1 1.1 GL33S 3.3V, CMOS Input Levels3, No Pull-up Resistor, Schmitt Trigger 1.1 1.1 PECL PPECL Input Levels 1.1 1.1 Max. tINYH1 Max. tINYL2 Std. Std. 1.0 1.1 1.4 1.0 Notes: 1. 2. 3. 4. tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3V for delays. Table 1-42 • Worst-Case Military Conditions VDDP = 2.3V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Macro Type GL25LP GL25LPS Description 2.5V, CMOS Input Levels3, Low Power 3, 2.5V, CMOS Input Levels Low Power, Schmitt Trigger Notes: 1. 2. 3. 4. 1 -5 2 tINYH = Input Pad-to-Y High tINYL = Input Pad-to-Y Low LVTTL delays are the same as CMOS delays. For LP Macros, VDDP=2.3V for delays. v5.8 ProASICPLUS Flash Family FPGAs Predicted Global Routing Delay Table 1-43 • Worst-Case Commercial Conditions1 VDDP = 3.0 V, VDD = 2.3 V, TJ = 70°C Max. Std. –F2 Units Input Low to High 3 1.1 1.3 ns Input High to Low 3 1.0 1.2 ns Input Low to High 4 0.8 1.0 ns Input High to Low 4 0.8 1.0 ns Parameter tRCKH tRCKL tRCKH tRCKL Description Notes: 1. 2. 3. 4. The timing delay difference between tile locations is less than 15ps. All –F parts are only available as commercial. Highly loaded row 50%. Minimally loaded row. Table 1-44 • Worst-Case Military Conditions VDDP = 3.0V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Parameter Description Max. Units tRCKH Input Low to High (high loaded row of 50%) 1.1 ns tRCKL Input High to Low (high loaded row of 50%) 1.0 ns tRCKH Input Low to High (minimally loaded row) 0.8 ns tRCKL Input High to Low (minimally loaded row) 0.8 ns Note: * The timing delay difference between tile locations is less than 15 ps. Global Routing Skew Table 1-45 • Worst-Case Commercial Conditions VDDP = 3.0 V, VDD = 2.3 V, TJ = 70°C Max. Parameter Description Std. –F* Units tRCKSWH Maximum Skew Low to High 270 320 ps tRCKSHH Maximum Skew High to Low 270 320 ps Note: *All –F parts are only available as commercial. Table 1-46 • Worst-Case Commercial Conditions VDDP = 3.0V, VDD = 2.3V, TJ = 125°C for Military/MIL-STD-883 Parameter Description Max. Units tRCKSWH Maximum Skew Low to High 270 ps tRCKSHH Maximum Skew High to Low 270 ps v5.8 1-53 ProASICPLUS Flash Family FPGAs Module Delays A B C A Y 50%50% 50% 50% B C 50%50% 50% Y 50% 50% tDBLH tDALH 50% 50% tDCLH 50% tDCHL tDBHL tDAHL Figure 1-29 • Module Delays Sample Macrocell Library Listing Table 1-47 • Worst-Case Military Conditions1 VDD = 2.3 V, TJ = 70º C, TJ = 70°C, TJ = 125°C for Military/MIL-STD-883 –F2 Std. Cell Name Description Max Min Max Min Units NAND2 2-Input NAND 0.5 0.6 ns AND2 2-Input AND 0.7 0.8 ns NOR3 3-Input NOR 0.8 1.0 ns MUX2L 2-1 MUX with Active Low Select 0.5 0.6 ns OA21 2-Input OR into a 2-Input AND 0.8 1.0 ns XOR2 2-Input Exclusive OR 0.6 0.8 ns LDL Active Low Latch (LH/HL) LH3 0.9 1.1 HL3 0.8 0.9 CLK-Q DFFL ns ns tsetup 0.7 0.8 ns thold 0.1 0.2 ns Negative Edge-Triggered D-type Flip-Flop (LH/HL) CLK-Q ns LH3 0.9 1.1 HL3 0.8 1.0 ns tsetup 0.6 0.7 ns thold 0.0 0.0 ns Notes: 1. Intrinsic delays have a variable component, coupled to the input slope of the signal. These numbers assume an input slope typical of local interconnect. 2. All –F parts are only available as commercial. 3. LH and HL refer to the Q transitions from Low to High and High to Low, respectively. 1 -5 4 v5.8 ProASICPLUS Flash Family FPGAs Table 1-48 • Recommended Operating Conditions Limits Parameter Symbol Commercial/Industrial Military/MIL-STD-883 Maximum Clock Frequency* fCLOCK 180 MHz 180 MHz Maximum RAM Frequency* fRAM 150 MHz 150 MHz Maximum Rise/Fall Time on Inputs* • Schmitt Trigger Mode (10% to 90%) tR/tF N/A 100 ns • Non-Schmitt Trigger Mode (10% to 90%) tR/tF 100 ns 10 ns 180 MHz 180 MHz 10 MHz 10 MHz Maximum LVPECL Frequency* Maximum TCK Frequency (JTAG) fTCK Note: *All –F parts will be 20% slower than standard commercial devices. Table 1-49 • Slew Rates Measured at C = 30pF, Nominal Power Supplies and 25°C Type Trig. Level Rising Edge (ns) Slew Rate (V/ns) Falling Edge (ns) Slew Rate (V/ns) PCI Mode OB33PH 10%-90% 1.60 1.65 1.65 1.60 Yes OB33PN 10%-90% 1.57 1.68 3.32 0.80 No OB33PL 10%-90% 1.57 1.68 1.99 1.32 No OB33LH 10%-90% 3.80 0.70 4.84 0.55 No OB33LN 10%-90% 4.19 0.63 3.37 0.78 No OB33LL 10%-90% 5.49 0.48 2.98 0.89 No OB25LPHH 10%-90% 1.55 1.29 1.56 1.28 No OB25LPHN 10%-90% 1.70 1.18 2.08 0.96 No OB25LPHL 10%-90% 1.97 1.02 2.09 0.96 No OB25LPLH 10%-90% 3.57 0.56 3.93 0.51 No OB25LPLN 10%-90% 4.65 0.43 3.28 0.61 No OB25LPLL 10%-90% 5.52 0.36 3.44 0.58 No Notes: 1. Standard and –F parts. 2. All –F only available as commercial. v5.8 1-55 ProASICPLUS Flash Family FPGAs Table 1-50 • JTAG Switching Characteristics Description Symbol Min Max Unit Output delay from TCK falling to TDI, TMS tTCKTDI –4 4 ns TDO Setup time before TCK rising tTDOTCK 10 TDO Hold time after TCK rising tTCKTDO 0 TCK period tTCK RCK period tRCK 100 ns ns 2 100 1,000 ns 1,000 ns Notes: 1. For DC electrical specifications of the JTAG pins (TCK, TDI, TMS, TDO, TRST), refer to Table 1-22 on page 1-37 when VDDP = 2.5 V and Table 1-24 on page 1-41 when VDDP = 3.3 V. 2. If RCK is being used, there is no minimum on the TCK period. TCK tTCK TMS, TDI tTCKTDI TDO tTDOTCK tTCKTDO Figure 1-30 • JTAG Operation Timing 1 -5 6 v5.8 ProASICPLUS Flash Family FPGAs Embedded Memory Specifications This section discusses ProASICPLUS SRAM/FIFO embedded memory and its interface signals, including timing diagrams that show the relationships of signals as they pertain to single embedded memory blocks (Table 1-51). Table 1-13 on page 1-24 shows basic SRAM and FIFO configurations. Simultaneous read and write to the same location must be done with care. On such accesses the DI bus is output to the DO bus. Refer to the ProASICPLUS RAM and FIFO Blocks application note for more information. "Synchronous SRAM Read, Access Timed Output Strobe (Synchronous Transparent)" section on page 1-58 • "Synchronous SRAM Read, Pipeline Mode Outputs (Synchronous Pipelined)" section on page 1-59 • "Asynchronous SRAM Write" section on page 1-60 • "Asynchronous SRAM Read, Address Controlled, RDB=0" section on page 1-61 "Asynchronous SRAM Read, RDB Controlled" section on page 1-62 • "Synchronous SRAM Write" • Embedded Memory Specifications The difference between synchronous transparent and pipeline modes is the timing of all the output signals from the memory. In transparent mode, the outputs will change within the same clock cycle to reflect the data requested by the currently valid access to the memory. If clock cycles are short (high clock speed), the data requires most of the clock cycle to change to valid values (stable signals). Processing of this data in the same clock cycle is nearly impossible. Most designers add registers at all outputs of the memory to push the data processing into the next clock cycle. An entire clock cycle can then be used to process the data. To simplify use of this memory setup, suitable registers have been implemented as part of the memory primitive and are available to the user in the synchronous pipeline mode. In this mode, the output signals will change shortly after the second rising edge, following the initiation of the read access. Enclosed Timing Diagrams—SRAM Mode: • • Table 1-51 • Memory Block SRAM Interface Signals SRAM Signal Bits In/Out Description WCLKS 1 In Write clock used on synchronization on write side RCLKS 1 In Read clock used on synchronization on read side RADDR 8 In Read address RBLKB 1 In True read block select (active Low) RDB 1 In True read pulse (active Low) WADDR 8 In Write address WBLKB 1 In Write block select (active Low) DI 9 In Input data bits , can be used for parity In WRB 1 In Negative true write pulse DO 9 Out Output data bits , can be used for parity Out RPE 1 Out Read parity error (active High) WPE 1 Out Write parity error (active High) PARODD 1 In Selects Odd parity generation/detect when high, Even when low Note: Not all signals shown are used in all modes. v5.8 1-57 ProASICPLUS Flash Family FPGAs Synchronous SRAM Read, Access Timed Output Strobe (Synchronous Transparent) RCLKS Cycle Start RBD, RBLKB New Valid Address RADDR New Valid Data Out Old Data Out DO RPE tRACS tRDCS tRDCH tRACH tOCH tRPCH tCMH tCML tOCA tRPCA tCCYC Note: The plot shows the normal operation status. Figure 1-31 • Synchronous SRAM Read, Access Timed Output Strobe (Synchronous Transparent) Table 1-52 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns OCA New DO access from RCLKS ↑ 7.5 ns OCH Old DO valid from RCLKS ↑ RACH RADDR hold from RCLKS ↑ 0.5 ns RACS RADDR setup to RCLKS ↑ 1.0 ns RDCH RDB hold from RCLKS ↑ 0.5 ns RDCS RDB setup to RCLKS ↑ 1.0 ns RPCA New RPE access from RCLKS ↑ 9.5 ns RPCH Old RPE valid from RCLKS ↑ 3.0 3.0 Note: All –F speed grade devices are 20% slower than the standard numbers. 1 -5 8 v5.8 ns ns Notes ProASICPLUS Flash Family FPGAs Synchronous SRAM Read, Pipeline Mode Outputs (Synchronous Pipelined) RCLKS Cycle Start RDB, RBLKB New Valid Address RADDR DO New Valid Data Out Old Data Out RPE Old RPE Out New RPE Out tOCA tRACS tRACH tRPCH tRDCH tOCH tRDCS tRPCA tCMH tCML tCCYC Note: The plot shows the normal operation status. Figure 1-32 • Synchronous SRAM Read, Pipeline Mode Outputs (Synchronous Pipelined) Table 1-53 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = 0°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns OCA New DO access from RCLKS ↑ 2.0 ns OCH Old DO valid from RCLKS ↑ RACH RADDR hold from RCLKS ↑ 0.5 ns RACS RADDR setup to RCLKS ↑ 1.0 ns RDCH RDB hold from RCLKS ↑ 0.5 ns RDCS RDB setup to RCLKS ↑ 1.0 ns RPCA New RPE access from RCLKS ↑ 4.0 ns RPCH Old RPE valid from RCLKS ↑ 0.75 1.0 Notes ns ns Note: All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-59 ProASICPLUS Flash Family FPGAs Asynchronous SRAM Write WADDR WRB, WBLKB DI WPE tAWRS tAWRH tDWRH tWPDA tWPDH tDWRS tWRML tWRMH tWRCYC Note: The plot shows the normal operation status. Figure 1-33 • Asynchronous SRAM Write Table 1-54 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883B Symbol txxx Description Min. Max. Units Notes AWRH WADDR hold from WB ↑ 1.0 ns AWRS WADDR setup to WB ↓ 0.5 ns DWRH DI hold from WB ↑ 1.5 ns DWRS DI setup to WB ↑ 0.5 ns PARGEN is inactive. DWRS DI setup to WB ↑ 2.5 ns PARGEN is active. WPDA WPE access from DI 3.0 ns WPDH WPE hold from DI WPE is invalid, while PARGEN is active. WRCYC Cycle time 7.5 ns WRMH WB high phase 3.0 ns Inactive WRML WB low phase 3.0 ns Active 1.0 Note: All –F speed grade devices are 20% slower than the standard numbers. 1 -6 0 v5.8 ns ProASICPLUS Flash Family FPGAs Asynchronous SRAM Read, Address Controlled, RDB=0 RADDR DO RPE tOAH tRPAH tOAA tRPAA tACYC Note: The plot shows the normal operation status. Figure 1-34 • Asynchronous SRAM Read, Address Controlled, RDB=0 Table 1-55 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883B Symbol txxx Description Min. Max. Units ACYC Read cycle time 7.5 ns OAA New DO access from RADDR stable 7.5 ns OAH Old DO hold from RADDR stable RPAA New RPE access from RADDR stable RPAH Old RPE hold from RADDR stable 3.0 10.0 Notes ns ns 3.0 ns Note: All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-61 ProASICPLUS Flash Family FPGAs Asynchronous SRAM Read, RDB Controlled RB=(RDB+RBLKB) DO RPE tORDH tRPRDH tORDA tRPRDA tRDML tRDMH tRDCYC Note: The plot shows the normal operation status. Figure 1-35 • Asynchronous SRAM Read, RDB Controlled Table 1-56 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units Notes ORDA New DO access from RB ↓ ORDH Old DO valid from RB ↓ RDCYC Read cycle time 7.5 ns RDMH RB high phase 3.0 ns Inactive setup to new cycle RDML RB low phase 3.0 ns Active RPRDA New RPE access from RB ↓ 9.5 ns RPRDH Old RPE valid from RB ↓ 7.5 3.0 3.0 Note: All –F speed grade devices are 20% slower than the standard numbers. 1 -6 2 ns v5.8 ns ns ProASICPLUS Flash Family FPGAs Synchronous SRAM Write WCLKS Cycle Start WRB, WBLKB WADDR, DI WPE tWRCH, tWBCH tWRCS, tWBCS tDCS, tWDCS tWPCH tDCH, tWACH tWPCA tCMH tCML tCCYC Note: The plot shows the normal operation status. Figure 1-36 • Synchronous SRAM Write Table 1-57 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units Notes CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns DCH DI hold from WCLKS ↑ 0.5 ns DCS DI setup to WCLKS ↑ 1.0 ns WACH WADDR hold from WCLKS ↑ 0.5 ns WDCS WADDR setup to WCLKS ↑ 1.0 ns WPCA New WPE access from WCLKS ↑ 3.0 ns WPE is invalid while WPCH Old WPE valid from WCLKS ↑ ns PARGEN is active WRCH, WBCH WRB & WBLKB hold from WCLKS ↑ WRCS, WBCS WRB & WBLKB setup to WCLKS ↑ 0.5 0.5 ns 1.0 ns Notes: 1. On simultaneous read and write accesses to the same location, DI is output to DO. 2. All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-63 ProASICPLUS Flash Family FPGAs Synchronous Write and Read to the Same Location tCCYC tCMH tCML RCLKS DO New Data* Last Cycle Data WCLKS t WCLKRCLKH t WCLKRCLKS tOCH tOCA * New data is read if WCLKS ↑ occurs before setup time. The data stored is read if WCLKS ↑ occurs after hold time. Note: The plot shows the normal operation status. Figure 1-37 • Synchronous Write and Read to the Same Location Table 1-58 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns WCLKRCLKS WCLKS ↑ to RCLKS ↑ setup time – 0.1 ns WCLKRCLKH WCLKS ↑ to RCLKS ↑ hold time 7.0 ns OCH Old DO valid from RCLKS ↑ 3.0 ns OCA New DO valid from RCLKS ↑ 7.5 ns Notes OCA/OCH displayed for Access Timed Output Notes: 1. This behavior is valid for Access Timed Output and Pipelined Mode Output. The table shows the timings of an Access Timed Output. 2. During synchronous write and synchronous read access to the same location, the new write data will be read out if the active write clock edge occurs before or at the same time as the active read clock edge. The negative setup time insures this behavior for WCLKS and RCLKS driven by the same design signal. 3. If WCLKS changes after the hold time, the data will be read. 4. A setup or hold time violation will result in unknown output data. 5. All –F speed grade devices are 20% slower than the standard numbers. 1 -6 4 v5.8 ProASICPLUS Flash Family FPGAs Asynchronous Write and Synchronous Read to the Same Location t CMH t CML RCLKS New Data* DO Last Cycle Data WB = {WRB + WBLKB} DI t WRCKS t BRCLKH t OCH t OCA t DWRRCLKS t DWRH tCCYC * New data is read if WB ↓ occurs before setup time. The stored data is read if WB ↓ occurs after hold time. Note: The plot shows the normal operation status. Figure 1-38 • Asynchronous Write and Synchronous Read to the Same Location Table 1-59 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns WBRCLKS WB ↓ to RCLKS ↑ setup time –0.1 ns WBRCLKH WB ↓ to RCLKS ↑ hold time 7.0 ns OCH Old DO valid from RCLKS ↑ 3.0 ns OCA New DO valid from RCLKS ↑ DWRRCLKS DI to RCLKS ↑ setup time DWRH DI to WB ↑ hold time 7.5 ns 0 ns 1.5 Notes OCA/OCH displayed Access Timed Output for ns Notes: 1. This behavior is valid for Access Timed Output and Pipelined Mode Output. The table shows the timings of an Access Timed Output. 2. In asynchronous write and synchronous read access to the same location, the new write data will be read out if the active write signal edge occurs before or at the same time as the active read clock edge. If WB changes to low after hold time, the data will be read. 3. A setup or hold time violation will result in unknown output data. 4. All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-65 ProASICPLUS Flash Family FPGAs Asynchronous Write and Read to the Same Location RB, RADDR DO NEW OLD NEWER WB = {WRB+WBLKB} tORDA tRAWRH tORDH tRAWRS tOWRA tOWRH Note: The plot shows the normal operation status. Figure 1-39 • Asynchronous Write and Read to the Same Location Table 1-60 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units ORDA New DO access from RB ↓ ORDH Old DO valid from RB ↓ OWRA New DO access from WB ↑ OWRH Old DO valid from WB ↑ RAWRS RB ↓ or RADDR from WB ↓ 5.0 ns RAWRH RB ↑ or RADDR from WB ↑ 5.0 ns 7.5 Notes ns 3.0 3.0 ns ns 0.5 ns Notes: 1. During an asynchronous read cycle, each write operation (synchronous or asynchronous) to the same location will automatically trigger a read operation which updates the read data. Refer to the ProASICPLUS RAM and FIFO Blocks application note for more information. 2. Violation or RAWRS will disturb access to the OLD data. 3. Violation of RAWRH will disturb access to the NEWER data. 4. All –F speed grade devices are 20% slower than the standard numbers. 1 -6 6 v5.8 ProASICPLUS Flash Family FPGAs Synchronous Write and Asynchronous Read to the Same Location RB, RADDR DO NEW OLD NEWER WCLKS t ORDA t RAWCLKH t ORDH t OWRA t OWRH t RAWCLKS Note: The plot shows the normal operation status. Figure 1-40 • Synchronous Write and Asynchronous Read to the Same Location Table 1-61 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units ORDA New DO access from RB ↓ ORDH Old DO valid from RB ↓ OWRA New DO access from WCLKS ↓ OWRH Old DO valid from WCLKS ↓ RAWCLKS RB ↓ or RADDR from WCLKS ↑ 5.0 ns RAWCLKH RB ↑ or RADDR from WCLKS ↓ 5.0 ns 7.5 Notes ns 3.0 3.0 ns ns 0.5 ns Notes: 1. During an asynchronous read cycle, each write operation (synchronous or asynchronous) to the same location will automatically trigger a read operation which updates the read data. 2. Violation of RAWCLKS will disturb access to OLD data. 3. Violation of RAWCLKH will disturb access to NEWER data. 4. All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-67 ProASICPLUS Flash Family FPGAs Asynchronous FIFO Full and Empty Transitions The asynchronous FIFO accepts writes and reads while not full or not empty. When the FIFO is full, all writes are inhibited. Conversely, when the FIFO is empty, all reads are inhibited. A problem is created if the FIFO is written to during the transition from full to not full, or read during the transition from empty to not empty. The exact time at which the write or read operation changes from inhibited to accepted after the read (write) signal which causes the transition from full or empty to not full or not empty is indeterminate. For slow cycles, this indeterminate period starts 1 ns after the RB (WB) transition, which deactivates full or not empty and ends 3 ns after the RB (WB) transition. For fast cycles, the indeterminate period ends 3 ns (7.5 ns – RDL (WRL)) after the RB (WB) transition, whichever is later (Table 1-1 on page 1-7). empty flag will be asserted, the counters will reset, the outputs go to zero, but the internal RAM is not erased. Enclosed Timing Diagrams – FIFO Mode: The following timing diagrams apply only to single cell; they are not applicable to cascaded cells. For more information, refer to the ProASICPLUS RAM/FIFO Blocks application note. The timing diagram for write is shown in Figure 1-38 on page 1-65. The timing diagram for read is shown in Figure 1-39 on page 1-66. For basic SRAM configurations, see Table 1-14 on page 1-25. When reset is asserted, the • "Asynchronous FIFO Read" section on page 1-70 • "Asynchronous FIFO Write" section on page 1-71 • "Synchronous FIFO Read, Access Timed Output Strobe (Synchronous Transparent)" section on page 1-72 • "Synchronous FIFO Read, Pipeline Mode Outputs (Synchronous Pipelined)" section on page 1-73 • "Synchronous FIFO Write" section on page 1-74 • "FIFO Reset" section on page 1-75 Table 1-62 • Memory Block FIFO Interface Signals FIFO Signal Bits In/Out Description WCLKS 1 In Write clock used for synchronization on write side RCLKS 1 In Read clock used for synchronization on read side LEVEL * 8 In Direct configuration implements static flag logic RBLKB 1 In Read block select (active Low) RDB 1 In Read pulse (active Low) RESET 1 In Reset for FIFO pointers (active Low) WBLKB 1 In Write block select (active Low) DI 9 In Input data bits , will be generated if PARGEN is true WRB 1 In Write pulse (active Low) FULL, EMPTY 2 Out FIFO flags. FULL prevents write and EMPTY prevents read EQTH, GEQTH* 2 Out EQTH is true when the FIFO holds the number of words specified by the LEVEL signal. GEQTH is true when the FIFO holds (LEVEL) words or more DO 9 Out Output data bits RPE 1 Out Read parity error (active High) WPE 1 Out Write parity error (active High) LGDEP 3 In Configures DEPTH of the FIFO to 2 (LGDEP+1) PARODD 1 In Selects Odd parity generation/detect when high, Even when low Note: *LEVEL is always eight bits (0000.0000, 0000.0001). That means for values of DEPTH greater than 256, not all values will be possible, e.g. for DEPTH=512, the LEVEL can only have the values 2, 4, . . ., 512. The LEVEL signal circuit will generate signals that indicate whether the FIFO is exactly filled to the value of LEVEL (EQTH) or filled equal or higher (GEQTH) than the specified LEVEL. Since counting starts at 0, EQTH will become true when the FIFO holds (LEVEL+1) words for 512-bit FIFOs. 1 -6 8 v5.8 ProASICPLUS Flash Family FPGAs FULL RB Write cycle Write inhibited Write accepted 1 ns 3 ns WB Note: All –F speed grade devices are 20% slower than the standard numbers. Figure 1-41 • Write Timing Diagram EMPTY WB Read cycle Read inhibited Read accepted 1 ns 3 ns RB Note: All –F speed grade devices are 20% slower than the standard numbers. Figure 1-42 • Read Timing Diagram v5.8 1-69 ProASICPLUS Flash Family FPGAs Asynchronous FIFO Read tRPRDA tRDL Cycle Start tRDH RB = (RDB+RBLKB) (Empty inhibits read) RDATA RPE WB EMPTY FULL EQTH, GETH tRDWRS tERDH, tFRDH tERDA, tFRDA tORDH tRPRDH tTHRDH tTHRDA tORDA tRPRDA tRDL tRDH tRDCYC Note: The plot shows the normal operation status. Figure 1-43 • Asynchronous FIFO Read Table 1-63 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. ERDH, FRDH, Old EMPTY, FULL, EQTH, & GETH valid hold THRDH time from RB ↑ ERDA New EMPTY access from RB ↑ FRDA Max. Units Notes 0.5 ns Empty/full/thresh are invalid from the end of hold until the new access is complete 3.01 ns FULL↓ access from RB ↑ 1 3.0 ns ORDA New DO access from RB ↓ 7.5 ns ORDH Old DO valid from RB ↓ RDCYC Read cycle time RDWRS WB ↑, clearing EMPTY, setup to RB ↓ 3.0 RDH RB high phase RDL 3.0 7.5 ns ns 2 ns Enabling the read operation ns Inhibiting the read operation 3.0 ns Inactive RB low phase 3.0 ns Active RPRDA New RPE access from RB ↓ 9.5 ns RPRDH Old RPE valid from RB ↓ THRDA EQTH or GETH access from RB↑ 1.0 4.0 4.5 Notes: 1. At fast cycles, ERDA and FRDA = MAX (7.5 ns – RDL), 3.0 ns. 2. At fast cycles, RDWRS (for enabling read) = MAX (7.5 ns – WRL), 3.0 ns. 3. All –F speed grade devices are 20% slower than the standard numbers. 1 -7 0 v5.8 ns ns ProASICPLUS Flash Family FPGAs Asynchronous FIFO Write Cycle Start WB = (WRB+WBLKB) WDATA (Full inhibits write) WPE RB FULL EMPTY EQTH, GETH tWRRDS tDWRH tWPDH tWPDA tDWRS tEWRH, tFWRH tEWRA, tFWRA tTHWRH tTHWRA tWRL tWRH tWRCYC Note: The plot shows the normal operation status. Figure 1-44 • Asynchronous FIFO Write Table 1-64 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Description Symbol txxx Min. Max. Units Notes DWRH DI hold from WB ↑ 1.5 DWRS DI setup to WB ↑ 0.5 ns PARGEN is inactive DWRS DI setup to WB ↑ 2.5 ns PARGEN is active ns Empty/full/thresh are invalid from the end of hold until the new access is complete EWRH, FWRH, Old EMPTY, FULL, EQTH, & GETH valid hold THWRH time after WB ↑ ns 0.5 EWRA EMPTY ↓ access from WB ↑ 3.01 ns FWRA New FULL access from WB ↑ 3.01 ns THWRA EQTH or GETH access from WB ↑ 4.5 ns WPDA WPE access from DI 3.0 ns WPDH WPE hold from DI WRCYC Cycle time 7.5 WRRDS RB ↑, clearing FULL, setup to WB ↓ 3.02 1.0 WPE is invalid while PARGEN is active ns ns ns 1.0 Enabling the write operation Inhibiting the write operation WRH WB high phase 3.0 ns Inactive WRL WB low phase 3.0 ns Active Notes: 1. 2. 3. 4. At fast cycles, EWRA, FWRA = MAX (7.5 ns – WRL), 3.0 ns. At fast cycles, WRRDS (for enabling write) = MAX (7.5 ns – RDL), 3.0 ns. All –F speed grade devices are 20% slower than the standard numbers. After FIFO reset, WRB needs an initial falling edge prior to any write actions. v5.8 1-71 ProASICPLUS Flash Family FPGAs Synchronous FIFO Read, Access Timed Output Strobe (Synchronous Transparent) RCLK Cycle Start RDB RDATA Old Data Out New Valid Data Out (Empty Inhibits Read) RPE EMPTY FULL EQTH, GETH tRDCH tRDCS tECBH, tFCBH tECBA, tFCBA tTHCBH tOCH tRPCH tHCBA tOCA tRPCA tCMH tCML tCCYC Note: The plot shows the normal operation status. Figure 1-45 • Synchronous FIFO Read, Access Timed Output Strobe (Synchronous Transparent) Table 1-65 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Description Symbol txxx Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns ECBA New EMPTY access from RCLKS ↓ 3.01 ns FCBA FULL ↓ access from RCLKS ↓ 3.01 ns ECBH, FCBH, Old EMPTY, FULL, EQTH, & GETH valid hold THCBH time from RCLKS ↓ 1.0 ns OCA New DO access from RCLKS ↑ OCH Old DO valid from RCLKS ↑ RDCH RDB hold from RCLKS ↑ 0.5 ns RDCS RDB setup to RCLKS ↑ 1.0 ns RPCA New RPE access from RCLKS ↑ 9.5 ns RPCH Old RPE valid from RCLKS ↑ HCBA EQTH or GETH access from RCLKS ↓ 7.5 ns 3.0 3.0 4.5 Notes: 1. At fast cycles, ECBA and FCBA = MAX (7.5 ns – CMH), 3.0 ns. 2. All –F speed grade devices are 20% slower than the standard numbers. 1 -7 2 v5.8 ns ns ns Notes Empty/full/thresh are invalid from the end of hold until the new access is complete ProASICPLUS Flash Family FPGAs Synchronous FIFO Read, Pipeline Mode Outputs (Synchronous Pipelined) RCLK Cycle Start RDB RDATA Old Data Out RPE New Valid Data Out Old RPE Out New RPE Out EMPTY FULL EQTH, GETH tECBH, tFCBH tOCA tRDCH tECBA, tFCBA tTHCBH tRDCS tRPCH tOCH tHCBA tRPCA tCMH tCML tCCYC Note: The plot shows the normal operation status. Figure 1-46 • Synchronous FIFO Read, Pipeline Mode Outputs (Synchronous Pipelined) Table 1-66 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns ECBA New EMPTY access from RCLKS ↓ 3.01 ns FCBA FULL ↓ access from RCLKS ↓ 1 ns ECBH, THCBH 3.0 FCBH, Old EMPTY, FULL, EQTH, & GETH valid hold time from RCLKS ↓ 1.0 ns OCA New DO access from RCLKS ↑ OCH Old DO valid from RCLKS ↑ RDCH RDB hold from RCLKS ↑ 0.5 ns RDCS RDB setup to RCLKS ↑ 1.0 ns RPCA New RPE access from RCLKS ↑ 4.0 ns RPCH Old RPE valid from RCLKS ↑ HCBA EQTH or GETH access from RCLKS ↓ 2.0 Notes Empty/full/thresh are invalid from the end of hold until the new access is complete ns 0.75 1.0 4.5 ns ns ns Notes: 1. At fast cycles, ECBA and FCBA = MAX (7.5 ns – CMS), 3.0 ns. 2. All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-73 ProASICPLUS Flash Family FPGAs Synchronous FIFO Write WCLKS Cycle Start WRB, WBLKB (Full Inhibits Write) DI WPE FULL EMPTY EQTH, GETH tWRCH, tWBCH tECBH, tFCBH tECBA, tFCBA tWRCS, tWBCS tDCS tHCBH tHCBA tWPCH tDCH tWPCA tCMH tCML tCCYC Note: The plot shows the normal operation status. Figure 1-47 • Synchronous FIFO Write Table 1-67 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units CCYC Cycle time 7.5 ns CMH Clock high phase 3.0 ns CML Clock low phase 3.0 ns DCH DI hold from WCLKS ↑ 0.5 ns DCS DI setup to WCLKS ↑ 1.0 ns FCBA New FULL access from WCLKS ↓ 3.01 ns ECBA EMPTY↓ access from WCLKS ↓ 3.01 ns ECBH, FCBH, HCBH Old EMPTY, FULL, EQTH, & GETH valid hold time from WCLKS ↓ HCBA EQTH or GETH access from WCLKS ↓ 4.5 ns WPCA New WPE access from WCLKS ↑ 3.0 ns WPCH Old WPE valid from WCLKS ↑ WRCH, WBCH WRB & WBLKB hold from WCLKS ↑ WRCS, WBCS WRB & WBLKB setup to WCLKS ↑ 1.0 0.5 ns 0.5 ns 1.0 ns Notes: 1. At fast cycles, ECBA and FCBA = MAX (7.5 ns – CMH), 3.0 ns. 2. All –F speed grade devices are 20% slower than the standard numbers. 1 -7 4 ns v5.8 Notes Empty/full/thresh are invalid from the end of hold until the new access is complete WPE is invalid, while PARGEN is active ProASICPLUS Flash Family FPGAs FIFO Reset RESETB Cycle Start WRB/RBD1 WCLKS, RCLKS1 Cycle Start FULL EMPTY EQTH, GETH tCBRSS tERSA, tFRSA tCBRSH tWBRSH tTHRSA tRSL tWBRSS Notes: 1. During reset, either the enables (WRB and RBD) OR the clocks (WCLKS and RCKLS) must be low. 2. The plot shows the normal operation status. Figure 1-48 • FIFO Reset Table 1-68 • TJ = 0°C to 110°C; VDD = 2.3 V to 2.7 V for Commercial/industrial TJ = –55°C to 150°C, VDD = 2.3 V to 2.7 V for Military/MIL-STD-883 Symbol txxx Description Min. Max. Units Notes CBRSH1 WCLKS or RCLKS ↑ hold from RESETB ↑ 1.5 ns Synchronous mode only CBRSS1 WCLKS or RCLKS ↓ setup to RESETB ↑ 1.5 ns Synchronous mode only ERSA New EMPTY ↑ access from RESETB ↓ 3.0 ns FRSA FULL ↓ access from RESETB ↓ 3.0 ns RSL RESETB low phase 7.5 ns EQTH or GETH access from RESETB ↓ 4.5 ns 1 WB ↓ hold from RESETB ↑ 1.5 ns Asynchronous mode only 1 WB ↑ setup to RESETB ↑ 1.5 ns Asynchronous mode only THRSA WBRSH WBRSS Notes: 1. During rest, the enables (WRB and RBD) must be high OR the clocks (WCLKS and RCKLS) must be low. 2. All –F speed grade devices are 20% slower than the standard numbers. v5.8 1-75 Pin Description TCK User Input/Output The I/O pin functions as an input, output, tristate, or bidirectional buffer. Input and output signal levels are compatible with standard LVTTL and LVCMOS specifications. Unused I/O pins are configured as inputs with pull-up resistors. NC No Connect To maintain compatibility with other Actel ProASICPLUS products, it is recommended that this pin not be connected to the circuitry on the board. GL Global Pin Low skew input pin for clock or other global signals. This pin can be configured with an internal pull-up resistor. When it is not connected to the global network or the clock conditioning circuit, it can be configured and used as a normal I/O. GLMX Global Multiplexing Pin Low skew input pin for clock or other global signals. This pin can be used in one of two special ways (refer to Actel’s Using ProASICPLUS Clock Conditioning Circuits). When the external feedback option is selected for the PLL block, this pin is routed as the external feedback source to the clock conditioning circuit. In applications where two different signals access the same global net at different times through the use of GLMXx and GLMXLx macros, this pin will be fixed as one of the source pins. This pin can be configured with an internal pull-up resistor. When it is not connected to the global network or the clock conditioning circuit, it can be configured and used as any normal I/O. If not used, the GLMXx pin will be configured as an input with pull-up. Dedicated Pins GND Ground Common ground supply voltage. VDD Logic Array Power Supply Pin 2.5 V supply voltage. VDDP Test Mode Select The TMS pin controls the use of boundary-scan circuitry. This pin has an internal pull-up resistor. User Pins I/O TMS I/O Pad Power Supply Pin 2.5 V or 3.3 V supply voltage. Test Clock Clock input pin for boundary scan (maximum 10 MHz). Actel recommends adding a nominal 20 kΩ pull-up resistor to this pin. TDI Test Data In Serial input for boundary scan. A dedicated pull-up resistor is included to pull this pin high when not being driven. TDO Test Data Out Serial output for boundary scan. Actel recommends adding a nominal 20kΩ pull-up resistor to this pin. TRST Test Reset Input Asynchronous, active-low input pin for resetting boundary-scan circuitry. This pin has an internal pull-up resistor. For more information, please refer to Power-up Behavior of ProASICPLUS Devices application note. Special Function Pins RCK Running Clock A free running clock is needed during programming if the programmer cannot guarantee that TCK will be uninterrupted. If not used, this pin has an internal pullup and can be left floating. NPECL User Negative Input Provides high speed clock or data signals to the PLL block. If unused, leave the pin unconnected. PPECL User Positive Input Provides high speed clock or data signals to the PLL block. If unused, leave the pin unconnected. AVDD PLL Power Supply Analog VDD should be VDD (core voltage) 2.5 V (nominal) and be decoupled from GND with suitable decoupling capacitors to reduce noise. For more information, refer to Actel’s Using ProASICPLUS Clock Conditioning Circuits application note. If the clock conditioning circuitry is not used in a design, AVDD can either be left floating or tied to 2.5 V. AGND PLL Power Ground The analog ground can be connected to the system ground. For more information, refer to Actel’s Using ProASICPLUS Clock Conditioning Circuits application note. If the PLLs or clock conditioning circuitry are not used in a design, AGND should be tied to GND. ProASICPLUS Flash Family FPGAs VPP finite length conductors that distribute the power to the device. This can be accomplished by providing sufficient bypass capacitance between the VPP and VPN pins and GND (using the shortest paths possible). Without sufficient bypass capacitance to counteract the inductance, the VPP and VPN pins may incur a voltage spike beyond the voltage that the device can withstand. This issue applies to all programming configurations. Programming Supply Pin This pin may be connected to any voltage between GND and 16.5 V during normal operation, or it can be left unconnected.2 For information on using this pin during programming, see the In-System Programming ProASICPLUS Devices application note. Actel recommends floating the pin or connecting it to VDDP. VPN Programming Supply Pin Recommended Design Practice for VPN/VPP The solution prevents spikes from damaging the ProASICPLUS devices. Bypass capacitors are required for the VPP and VPN pads. Use a 0.01 µF to 0.1 µF ceramic capacitor with a 25 V or greater rating. To filter lowfrequency noise (decoupling), use a 4.7 µF (low ESR,
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