FINAL COM’L: -12/15/20 MACH445-12/15/20 Lattice Semiconductor High-Density EE CMOS Programmable Logic DISTINCTIVE CHARACTERISTICS ■ 100-pin version of the MACH435 in PQFP ■ Up to 20 product terms per function, with XOR ■ 5 V, in-circuit programmable ■ Flexible clocking ■ JTAG, IEEE 1149.1 JTAG testing capability — Four global clock pins with selectable edges — Asynchronous mode available for each macrocell ■ 8 “PAL33V16” blocks ■ 128 macrocells ■ 12 ns tPD ■ 83 MHz fCNT ■ 70 inputs with pull-up resistors ■ Input and output switch matrices for high routability ■ 64 outputs ■ Fixed, predictable, deterministic delays ■ 192 flip-flops ■ JEDEC-file compatible with MACH435 — 128 macrocell flip-flops — 64 input flip-flops ■ Zero-hold-time input register option GENERAL DESCRIPTION The MACH445 is a member of the high-performance EE CMOS MACH 4 family. This device has approximately twelve times the macrocell capability of the popular PAL22V10, with significant density and functional features that the PAL22V10 does not provide. It is architecturally identical to the MACH435, with the addition of JTAG and 5-V programming features. The MACH445 consists of eight PAL blocks interconnected by a programmable central switch matrix. The central switch matrix connects the PAL blocks to each other and to all input pins, providing a high degree of connectivity between the fully-connected PAL blocks. This allows designs to be placed and routed efficiently. Routability is further enhanced by an input switch matrix and an output switch matrix. The input switch matrix provides input signals with alternative paths into the central switch matrix; the output switch matrix provides flexibility in assigning macrocells to I/O pins. The MACH445 has macrocells that can be configured as synchronous or asynchronous. This allows designers to implement both synchronous and asynchronous logic together on the same device. The two types of design can be mixed in any proportion, since the selection on each macrocell affects only that macrocell. Up to 20 product terms per function can be assigned. It is possible to allocate some product terms away from a macrocell without losing the use of that macrocell for logic generation. The MACH445 macrocell provides either registered or combinatorial outputs with programmable polarity. If a registered configuration is chosen, the register can be configured as D-type, T-type, J-K, or S-R to help reduce the number of product terms used. The flip-flop can also be configured as a latch. The register type decision can be made by the designer or by the software. All macrocells can be connected to an I/O cell through the output switch matrix. The output switch matrix makes it possible to make significant design changes while minimizing the risk of pinout changes. Publication# 17468 Rev. E Issue Date: May 1995 Amendment /0 2 4 4 Clock Generator OE CLK0/I0, CLK1/I1, CLK2/I3, CLK3/I4 MACH445-12/15/20 4 Block G 8 I/O Cells 8 Output Switch Matrix I/O48–I/O55 4 8 Block H Clock Generator I/O56–I/O63 8 I/O Cells 8 16 16 16 Input Switch Matrix 16 Macrocells 4 4 8 Clock Generator 17468E-1 Block F I/O40–I/O47 8 I/O Cells 8 Output Switch Matrix 16 Macrocells 16 66 X 90 AND Logic Array and Logic Allocator 24 16 16 4 4 4 4 4 8 8 OE Output Switch Matrix OE 4 OE 16 Input Switch Matrix 16 4 33 24 Input Switch Matrix 8 OE Macrocells OE 16 66 X 90 AND Logic Array and Logic Allocator 24 16 16 4 Block D Block E I/O32–I/O39 8 I/O Cells 8 Output Switch Matrix 16 Macrocells 16 66 X 90 AND Logic Array and Logic Allocator 33 33 66 X 90 AND Logic Array and Logic Allocator 16 Macrocells 16 Output Switch Matrix 8 I/O Cells 8 I/O24–I/031 16 16 24 24 16 16 Input Switch Matrix 4 4 33 66 X 90 AND Logic Array and Logic Allocator 16 Macrocells 16 Output Switch Matrix Central Switch Matrix 4 4 8 8 OE 16 66 X 90 AND Logic Array and Logic Allocator Input Switch Matrix 24 Input Switch Matrix 33 16 16 OE 24 33 66 X 90 AND Logic Array and Logic Allocator 16 Macrocells 16 Output Switch Matrix 4 I/O Cells 8 Input Switch Matrix 24 4 4 8 8 Block C I/O16–I/O23 Input Switch Matrix 33 33 16 16 Clock Generator 66 X 90 AND Logic Array and Logic Allocator 16 Macrocells 16 Output Switch Matrix 4 I/O Cells 8 Clock Generator 4 8 8 I/O Cells 8 Block B I/O8–I/O15 Clock Generator 4 4 4 Block A I/O0–I/O7 2 BLOCK DIAGRAM I2, I5 Clock Generator Clock Generator CONNECTION DIAGRAM MACH445 (MACH435) Top View PQFP BLOCK H (62) (61) (60) (59) (58) (57) (56) (55) (54) (41) GND GND TD0 TRST* I/O55 I/O54 I/O53 I/O52 I/O51 I/O50 I/O49 I/O48 I4/CLK3 GND GND VCC VCC I3/CLK2 I/O47 I/O46 I/O45 I/O44 I/O43 I/O42 I/O41 I/O40 I2 ENABLE* GND GND BLOCK G (73) (72) (71) (70) (69) (68) (67) (66) (65) 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 BLOCK F (82) (81) (80) (79) (78) (77) (76) (75) 92 91 90 89 88 87 86 85 84 83 82 81 (10) 100 (9) 99 (8) 98 (7) 97 (6) 96 (5) 95 (4) 94 (3) 93 1 2 3 4 (83) 5 (12) 6 (13) 7 (14) 8 (15) 9 (16) 10 (17) 11 (18) 12 (19) 13 (20) 14 15 16 17 18 (23) 19 (24) 20 (25) 21 (26) 22 (27) 23 (28) 24 (29) 25 (30) 26 (31) 27 28 29 30 31 (33) 32 (34) 33 (35) 34 (36) 35 (37) 36 (38) 37 (39) 38 (40) 39 40 41 42 43 (45) 44 (46) 45 (47) 46 (48) 47 (49) 48 (50) 49 (51) 50 (52) GND GND TDI I5 I/O8 I/O9 I/O10 I/O11 I/O12 I/O13 I/O14 I/O15 I0/CLK0 VCC VCC GND GND I1/CLK1 I/O16 I/O17 I/O18 I/O19 I/O20 I/O21 I/O22 I/O23 TMS TCK GND GND I/O24 I/O25 I/O26 I/O27 I/O28 I/O29 I/O30 I/O31 VCC GND GND VCC I/O32 I/O33 I/O34 I/O35 I/O36 I/O37 I/O38 I/O39 BLOCK C BLOCK B I/O7 I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0 VCC GND GND VCC I/O63 I/O62 I/O61 I/O60 I/O59 I/O58 I/O57 I/O56 BLOCK A BLOCK D BLOCK E 17468E-2 PIN DESIGNATIONS CLK/I GND I I/O VCC = = = = = Clock or Input Ground Input Input/Output Supply Voltage MACH445-12/15/20 3 ORDERING INFORMATION Commercial Products Programmable logic products for commercial applications are available with several ordering options. The order number (Valid Combination) is formed by a combination of: MACH 445 -12 Y FAMILY TYPE MACH = Macro Array CMOS High-Speed OPTIONAL PROCESSING Blank = Shipped in Trays DEVICE NUMBER 445 = 2nd Generation, 128 Macrocells, 100 Pins OPERATING CONDITIONS C = Commercial (0°C to +70°C) PACKAGE TYPE Y = 100-Pin Plastic Quad Flat Pack (PQR100) SPEED -12 = 12 ns tPD -15 = 15 ns tPD -20 = 20 ns tPD Valid Combinations MACH445-12 MACH445-15 MACH445-20 4 C YC Valid Combinations The Valid Combinations table lists configurations planned to be supported in volume for this device. Consult your local sales office to confirm availability of specific valid combinations and to check on newly released combinations. MACH445-12/15/20 FUNCTIONAL DESCRIPTION The Clock Generator The MACH445 consists of eight PAL blocks connected by a central switch matrix. There are 64 I/O pins and 6 dedicated input pins feeding the central switch matrix. These signals are distributed to the eight PAL blocks for efficient design implementation. There are 4 global clock pins that can also be used as dedicated inputs. Each PAL block has a clock generator that can generate four clock signals for use throughout the PAL block. These four signals are available to all macrocells and I/O cells in the PAL block, whether in synchronous or asynchronous mode. The clock generator chooses the four signals from the eight possible signals given by the true and complement versions of the four global clock pin signals. All inputs and I/O pins have built-in pull-up resistors. While it is always good design practice to tie unused pins high, the pull-up resistors provide design security and stability in the event that unused pins are left disconnected. The PAL Blocks Each PAL block in the MACH445 (Figure 1) contains a clock generator, a 90-product-term logic array, a logic allocator, 16 macrocells, an output switch matrix, 8 I/O cells, and an input switch matrix. The central switch matrix feeds each PAL block with 33 inputs. This makes the PAL block look effectively like an independent “PAL33V16” with 8 to 16 buried macrocells. In addition to the logic product terms, individual output enable product terms and two PAL block initialization product terms are provided. Each I/O pin can be individually enabled. All flip-flops that are in the synchronous mode within a PAL block are initialized together by either of the PAL block nitialization product terms. The Central Switch Matrix and Input Switch Matrix The MACH445 central switch matrix is fed by the input switch matrices in each PAL block. Each PAL block provides 16 internal feedback signals, 8 registered input signals, and 8 I/O pin signals to the input switch matrix. Of these 32 signals, 24 decoded signals are provided to the central switch matrix by the input switch matrix. The central switch matrix distributes these signals back to the PAL blocks in a very efficient manner that provides for high performance. The design software automatically configures the input and central switch matrices when fitting a design into the device. The Product-Term Array The MACH445 product-term array consists of 80 product terms for logic use, eight product terms for output enable use, and two product terms for global PAL block initialization. Each macrocell has a nominal allocation of 5 product terms for logic, although the logic allocator allows for logic redistribution. Each I/O pin has its own individual output enable term. The initialization product terms provide asynchronous reset or preset to synchronous-mode macrocells in the PAL block. The Logic Allocator The logic allocator in the MACH445 takes the 80 logic product terms and allocates them to the 16 macrocells as needed. Each macrocell can be driven by up to 20 product terms in synchronous mode, or 18 product terms in asynchronous mode. When product terms are routed away from a macrocell, all 5 product terms may be redirected, which precludes the use of the macrocell for logic generation. It is possible to redirect only 4 product terms, leaving one for simple function generation. The design software automatically configures the logic allocator when fitting the design into the device. The logic allocator also provides an exclusive-OR gate. This gate allows generation of combinatorial exclusiveOR logic, such as comparison or addition. It allows registered exclusive-OR functions, such as CRC generation, to be implemented more efficiently. Emulating all flip-flop types with a D-type flip-flop is also made possible. Register type emulation is automatically handled by the design software. Table 1 illustrates which product term clusters are available to each macrocell within a PAL block. Refer to Figure 1 for cluster and macrocell numbers. MACH445-12/15/20 5 Table 9. Logic Allocation Macrocell Available Clusters M0 C0, C1, C2 M1 C0, C1, C2, C3 M2 C1, C2, C3, C4 M3 C2, C3, C4, C5 M4 C3, C4, C5, C6 M5 C4, C5, C6, C7 M6 C5, C6, C7, C8 M7 C6, C7, C8, C9 M8 C7, C8, C9, C10 M9 C8, C9, C10, C11 M10 C9, C10, C11, C12 M11 C10, C11, C12, C13 M12 C11, C12, C13, C14 M13 C12, C13, C14, C15 M14 C13, C14, C15 M15 C14, C15 The flip-flop clock depends on the mode selected for the macrocell. In synchronous mode, any of the PAL block clocks generated by the Clock Generator can be used. In asynchronous mode, the additional choice of either edge of an individual product-term clock is available. The Macrocell and Output Switch Matrix The MACH445 has 16 macrocells, half of which can drive I/O pins; this selection is made by the output switch matrix. Each macrocell can drive one of four I/O cells. The allowed combinations are shown in Table 2. Please refer to Figure 1 for macrocell and I/O pin numbers. Table 2. Output Switch Matrix Combinations Macrocell M0, M1 M2, M3 M4, M5 M6, M7 M8, M9 M10, M11 M12, M13 M14, M15 I/O Pin I/O0 I/O1 I/O2 I/O3 I/O4 I/O5 I/O6 I/O7 6 The macrocells can be configured as registered, latched, or combinatorial. In combination with the logic allocator, the registered configuration can be any of the standard flip-flop types. The macrocell provides internal feedback whether configured with or without the flipflop, and whether or not the macrocell drives an I/O cell. Routable to I/O Pins I/O5, I/O6, I/O7, I/O0 I/O6, I/O7, I/O0, I/O1 I/O7, I/O0, I/O1, I/O2 I/O0, I/O1, I/O2, I/O3 I/O1, I/O2, I/O3, I/O4 I/O2, I/O3, I/O4, I/O5 I/O3, I/O4, I/O5, I/O6 I/O4, I/O5, I/O6, I/O7 Initialization can be handled as part of a bank of macrocells via the PAL block initialization terms if in synchronous mode, or individually if in asynchronous mode. In synchronous mode, one of the PAL block product terms is available each for preset and reset. The swap function determines which product term drives which function. This allows initialization polarity compatibility with the MACH 1 and 2 series. In asynchronous mode, one product term can be used either to drive reset or preset. The I/O Cell The I/O cell in the MACH445 consists of a three-state buffer and an input flip-flop. The I/O cell is driven by one of the macrocells, as selected by the output switch matrix. Each I/O cell can take its input from one of eight macrocells. The three-state buffer is controlled by an individual product term. The input flip-flop can be configured as a register or latch. Both the direct I/O signal and the registered/latched signal are available to the input switch matrix, and can be used simultaneously if desired. JTAG Testing JTAG is the commonly used acronym for the IEEE Standard 1149.1–1990. The JTAG standard defines input and output pins, logic control functions, and instructions. Lattice/Vantis has incorporated this standard into the MACH445 device. Available Macrocells M0, M1, M2, M3, M4, M5, M6, M7 M2, M3, M4, M5, M6, M7, M8, M9 M4, M5, M6, M7, M8, M9, M10, M11 M6, M7, M8, M9, M10, M11, M12, M13 M8, M9, M10, M11, M12, M13, M14, M15 M10, M11, M12, M13, M14, M15, M0, M1 M12, M13, M14, M15, M0, M1, M2, M3 M14, M15, M0, M1, M2, M3, M4, M5 The JTAG standard was developed as a means of providing both board-level and device-level testing. MACH445-12/15/20 Five-Volt Programming Zero-Hold-Time Input Register Another benefit from the JTAG circuitry that we have derived is the ability to use the JTAG port for five-volt programming. This allows the device to be soldered to the board before programming. Once the device is attached, the delicate Plastic Quad Flat Pack, or PQFP, leads are protected from programming and testing operations that could potentially damage them. Programming and verification of the device is done serially which is ideal for on-board programming since it only requires the use of the Test Access Port. Use of the programming Enable Pin (ENABLE*) is optional. The MACH445 device has a zero-hold time (ZHT) fuse. This fuse controls the time delay associated with loading data into all I/O cell registers and latches in the MACH445 device. When programmed, the ZHT fuse increases the data path setup delays to input storage elements, matching equivalent delays in the clock path. When the fuse is erased, the setup time to the input storage element is minimized and the device timing is compatible with the MACH435 device. This feature facilitates doing worst-case designs for which data is loaded from sources which have low (or zero) minimum output propagation delays from clock edges. MACH445-12/15/20 7 CLK2/I3 CLK3/I4 CLK0/I0 CLK1/I1 16 Clock Generator M0 Macrocell M0 C1 M1 Macrocell M1 C2 M2 Macrocell M2 C3 M3 Macrocell M3 C4 M4 Macrocell M4 C5 M5 Macrocell M5 C6 M6 Macrocell M6 M7 Macrocell M7 M8 Macrocell M8 C9 M9 Macrocell M9 C10 M10 Macrocell M10 C11 M11 Macrocell C12 M12 Macrocell M12 C13 M13 Macrocell M13 C14 M14 Macrocell M14 C15 M15 Macrocell M15 C7 C8 Output Switch Matrix C0 Logic Allocator Central Switch Matrix 4 O0 I/O Cell I/O0 O1 I/O Cell I/O1 O2 I/O Cell I/O2 O3 I/O Cell I/O3 O4 I/O Cell I/O4 O5 I/O Cell I/O5 O6 I/O Cell I/O6 O7 I/O Cell I/O7 M11 17 16 24 Input Switch Matrix 16 17468E-3 Figure 1. MACH445 PAL Block 8 MACH445-12/15/20 ABSOLUTE MAXIMUM RATINGS OPERATING RANGES Storage Temperature . . . . . . . . . . . –65°C to +150°C Ambient Temperature with Power Applied . . . . . . . . . . . . . –55°C to +125°C Supply Voltage with Respect to Ground . . . . . . . . . . . . . –0.5 V to +7.0 V DC Input Voltage . . . . . . . . . . . . –0.5 V to VCC +0.5 V DC Output or I/O Pin Voltage . . . . . . . . . . . . . –0.5 V to VCC +0.5 V Static Discharge Voltage . . . . . . . . . . . . . . . . . 2001 V Latchup Current (TA = 0°C to +70°C) . . . . . . . . . . . . . . . . . . . . 200 mA Commercial (C) Devices Temperature (TA) Operating in Free Air . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C Supply Voltage (VCC) with Respect to Ground . . . . . . . . . . . . +4.75 V to +5.25 V Operating ranges define those limits between which the functionality of the device is guaranteed. Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to Absolute Maximum Ratings for extended periods may affect device reliability. Programming conditions may differ. DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified Parameter Symbol Parameter Description Test Conditions Min Typ Max Unit VOH Output HIGH Voltage IOH = –3.2 mA, VCC = Min VIN = VIH or VIL 2.4 VOL Output LOW Voltage IOL = 24 mA, VCC = Min VIN = VIH or VIL (Note 1) VIH Input HIGH Voltage Guaranteed Input Logical HIGH Voltage for all Inputs (Note 2) VIL Input LOW Voltage Guaranteed Input Logical LOW Voltage for all Inputs (Note 2) 0.8 V IIH Input HIGH Leakage Current VIN = 5.25 V, VCC = Max (Note 3) 10 µA IIL Input LOW Leakage Current VIN = 0 V, VCC = Max (Note 3) –100 µA IOZH Off-State Output Leakage Current HIGH VOUT = 5.25 V, VCC = Max VIN = VIH or VIL (Note 3) 10 µA IOZL Off-State Output Leakage Current LOW VOUT = 0 V, VCC = Max VIN = VIH or VIL (Note 3) –100 µA ISC Output Short-Circuit Current VOUT = 0.5 V, VCC = Max (Note 4) –160 mA ICC Supply Current VIN = 0 V, Outputs Open (IOUT = 0 mA) VCC = 5.0 V, f =25 MHz, TA = 25°C (Note 5) V 0.5 V 2.0 V –30 255 mA CAPACITANCE (Note 6) Parameter Symbol CIN COUT Parameter Description Test Conditions Typ Unit Input Capacitance VIN = 2.0 V Output Capacitance VOUT = 2.0 V VCC = 5.0 V, TA = 25°C, 6 pF f = 1 MHz 8 pF Notes: 1. 2. 3. 4. Total IOL for one PAL block should not exceed 128 mA. These are absolute values with respect to device ground and all overshoots due to system or tester noise are included. I/O pin leakage is the worst case of IIL and IOZL (or IIH and IOZH). Not more than one output should be shorted at a time and duration of the short-circuit should not exceed one second. VOUT = 0.5 V has been chosen to avoid test problems caused by tester ground degradation. 5. Measured with a 16-bit up/down counter pattern. This pattern is programmed in each PAL block and capable of being loaded, enabled, and reset. 6. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified where capacitance may be affected. MACH445-12 (Com’l) 9 SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) Parameter Symbol -12 Parameter Description tPD Input, I/O, or Feedback to Combinatorial Output tSA Setup Time from Input, I/O, or Feedback to Product Term Clock Max Unit 3 12 ns D-type 5 ns T-type 6 ns ns tHA Register Data Hold Time Using Product Term Clock 5 tCOA Product Term Clock to Output 4 tWLA tWHA fMAXA Product Term, Clock Width Maximum Frequency Using Product Term Clock (Note 2) External Feedback Internal Feedback (f CNTA) tSS Setup Time from Input, I/O, or Feedback to Global Clock 8 ns 8 ns D-type 52.6 MHz T-type 50.0 MHz D-type 58.8 MHz T-type 55.6 MHz 62.5 MHz D-type 7 ns T-type 8 ns tHS Register Data Hold Time Using Global Clock 0 Global Clock to Output 2 Global Clock Width tWHS fMAXS Maximum Frequency Using Global Clock (Note 2) External Feedback Internal Feedback (f CNTS) No Feedback (Note 3) ns HIGH tCOS tWLS 14 LOW No Feedback (Note 3) 10 Min ns 8 ns LOW 6 ns HIGH 6 ns D-type 66.7 MHz T-type 62.5 MHz D-type 83.3 MHz T-type 76.9 MHz 83.3 MHz tSLA Setup Time from Input, I/O, or Feedback to Product Term Clock 5 ns tHLA Latch Data Hold Time Using Product Term Clock 5 ns tGOA Product Term Gate to Output tGWA Product Term Gate Width LOW (for LOW transparent) or HIGH (for HIGH transparent) 6 ns tSLS Setup Time from Input, I/O, or Feedback to Global Gate 8 ns tHLS Latch Data Hold Time Using Global Gate 0 ns tGOS Gate to Output tGWS Global Gate Width LOW (for LOW transparent) or HIGH (for HIGH transparent) tICO Input Register Clock to Combinatorial Output 16 10 MACH445-12 (Com’l) 6 ns ns ns 18 ns SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) (continued) Parameter Symbol tICS -12 Parameter Description Min Input Register Clock to Output Register Setup tWICL tWICH fMAXIR Input Register Clock Width Maximum Input Register Frequency 1/(t WICL + t WICH ) Max Unit D-type 9 ns T-type 10 ns LOW 6 ns HIGH 6 ns 83.3 MHz tIGO Input Latch Gate to Combinatorial Output 16 ns tIGOL Input Latch Gate to Output Through Transparent Output Latch 18 ns tIGSA Input Latch Gate to Output Latch Setup Using Product Term Output Latch Gate 4 ns tIGSS Input Latch Gate to Output Latch Setup Using Global Output Latch Gate 9 ns tWIGL Input Latch Gate Width LOW 6 ns tAR Asynchronous Reset to Registered or Latched Output 16 ns tARW Asynchronous Reset Width (Note 2) 12 ns tARR Asynchronous Reset Recovery Time (Note 2) 10 ns tAP Asynchronous Preset to Registered or Latched Output 16 ns tAPW Asynchronous Preset Width (Note 2) tAPR Asynchronous Preset Recovery Time (Note 2) tEA Input, I/O, or Feedback to Output Enable 2 12 ns tER Input, I/O, or Feedback to Output Disable 2 12 ns 14 ns 12 ns 8 ns Input Register with Standard-Hold-Time Option tPDL Input, I/O, or Feedback to Output Through Transparent Input Latch tSIR Input Register Setup Time 2 ns tHIR Input Register Hold Time 3 ns tSIL Input Latch Setup Time 2 ns tHIL Input Latch Hold Time 3 ns tSLLA Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Product Term Output Gate 4 ns tSLLS Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Output Gate 9 ns tPDLL Input, I/O, or Feedback to Output Through Transparent Input and Output Latches MACH445-12 (Com’l) 16 ns 11 SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) (continued) Parameter Symbol -12 Parameter Description Min Max Unit 20 ns Input Register with Zero-Hold-Time Option tPDL ❙ Input, I/O, or Feedback to Output Through Transparent Input Latch tSIR❙ Input Register Setup Time ❙ 6 ns Input Register Hold Time 0 ns Input Latch Setup Time 6 ns Input Latch Hold Time 0 ns Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Product Term Output Gate 16 ns tSLLS ❙ Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Output Gate 18 ns tPDLL ❙ Input, I/O, or Feedback to Output Through Transparent Input and Output Latches tHIR tSIL❙ tHIL❙ tSLLA ❙ 22 Notes: 1. See Switching Test Circuit at the end of this Data Book for test conditions. 2. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified where frequency may be affected. 3. This parameter does not apply to flip-flops in the emulated mode since the feedback path is required for emulation. 12 MACH445-12 (Com’l) ns ABSOLUTE MAXIMUM RATINGS OPERATING RANGES Storage Temperature . . . . . . . . . . . –65°C to +150°C Commercial (C) Devices Ambient Temperature with Power Applied . . . . . . . . . . . . . –55°C to +125°C Temperature (TA) Operating in Free Air . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C Supply Voltage with Respect to Ground . . . . . . . . . . . . . –0.5 V to +7.0 V Supply Voltage (VCC) with Respect to Ground . . . . . . . . . . . . +4.75 V to +5.25 V DC Input Voltage . . . . . . . . . . . –0.5 V to VCC +0.5 V DC Output or I/O Pin Voltage . . . . . . . . . . . . –0.5 V to VCC +0.5 V Static Discharge Voltage . . . . . . . . . . . . . . . . . 2001 V Latchup Current (TA = 0°C to +70°C) . . . . . . . . . . . . . . . . . . . . 200 mA Operating ranges define those limits between which the functionality of the device is guaranteed. Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to Absolute Maximum Ratings for extended periods may affect device reliability. Programming conditions may differ. DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified Parameter Symbol Parameter Description Test Conditions Min Typ Max Unit VOH Output HIGH Voltage IOH = –3.2 mA, VCC = Min VIN = VIH or VIL 2.4 VOL Output LOW Voltage IOL = 24 mA, VCC = Min VIN = VIH or VIL (Note 1) VIH Input HIGH Voltage Guaranteed Input Logical HIGH Voltage for all Inputs (Note 2) VIL Input LOW Voltage Guaranteed Input Logical LOW Voltage for all Inputs (Note 2) 0.8 V IIH Input HIGH Leakage Current VIN = 5.25 V, VCC = Max (Note 3) 10 µA IIL –100 µA 10 µA –100 µA –160 mA V 0.5 2.0 V V Input LOW Leakage Current VIN = 0 V, VCC = Max (Note 3) IOZH Off-State Output Leakage Current HIGH VOUT = 5.25 V, VCC = Max VIN = VIH or VIL (Note 3) IOZL Off-State Output Leakage Current LOW VOUT = 0 V, VCC = Max VIN = VIH or VIL (Note 3) ISC Output Short-Circuit Current VOUT = 0.5 V, VCC = Max (Note 4) –30 ICC Supply Current VIN = 0 V, Outputs Open (IOUT = 0 mA), VCC = 5.0 V, f =25 MHz TA = 25°C (Note 5) 255 mA CAPACITANCE (Note 6) Parameter Symbol CIN COUT Parameter Description Test Conditions Typ Unit Input Capacitance VIN = 2.0 V Output Capacitance VOUT = 2.0 V VCC = 5.0 V, TA = 25°C, 6 pF f = 1 MHz 8 pF Notes: 1. 2. 3. 4. Total IOL for one PAL block should not exceed 128 mA. These are absolute values with respect to device ground and all overshoots due to system or tester noise are included. I/O pin leakage is the worst case of IIL and IOZL (or IIH and IOZH). Not more than one output should be shorted at a time and duration of the short-circuit should not exceed one second. VOUT = 0.5 V has been chosen to avoid test problems caused by tester ground degradation. 5. Measured with a 16-bit up/down counter pattern. This pattern is programmed in each PAL block and capable of being loaded, enabled, and reset. An actual ICC value can be calculated by using the “Typical Dynamic ICC Characteristics” Chart towards the end of this data sheet. 6. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified where capacitance may be affected. MACH445-15/20 (Com’l) 13 SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) -15 Parameter Symbol Parameter Description tPD Input, I/O, or Feedback to Combinatorial Output (Note 2) tSA Setup Time from Input, I/O, or Feedback to Product Term Clock tHA Register Data Hold Time Using Product Term Clock tCOA Product Term Clock to Output (Note 2) tWLA Min Max Min Max Unit 3 15 3 20 ns D-type 8 10 ns T-type 9 11 ns 8 10 ns 4 Product Term, Clock Width tWHA -20 18 4 22 ns LOW 9 12 ns HIGH 9 12 ns D-type 38.5 31.2 MHz T-type 37 30.3 MHz D-type 47.6 37 MHz T-type 45.4 35.7 MHz 55.6 41.7 MHz D-type 10 13 ns T-type 11 14 ns 0 ns External Feedback 1/(t SA + t COA ) fMAXA tSS Maximum Frequency Using Product Term Clock (Note 3) Internal Feedback (f CNTA) No Feedback (Note 4) 1/(t WLA + t WHA ) Setup Time from Input, I/O, or Feedback to Global Clock tHS Register Data Hold Time Using Global Clock 0 tCOS Global Clock to Output (Note 2) 2 tWLS 10 2 12 ns LOW 6 8 ns HIGH 6 8 ns D-type 50 40 MHz T-type 47.6 38.5 MHz D-type 66.6 50 MHz T-type 62.5 47.6 MHz 83.3 62.5 MHz Global Clock Width tWHS External Feedback 1/(t fMAXS Maximum Frequency Using Global Clock (Note 3) Internal Feedback (f CNTS) No Feedback (Note 4) 14 SS + t COS ) 1/(t WLS + t WHS ) tSLA Setup Time from Input, I/O, or Feedback to Product Term Clock 8 10 ns tHLA Latch Data Hold Time Using Product Term Clock 8 10 ns tGOA Product Term Gate to Output (Note 2) tGWA Product Term Gate Width LOW (for LOW transparent) or HIGH (for HIGH transparent) 9 12 ns tSLS Setup Time from Input, I/O, or Feedback to Global Gate 10 13 ns tHLS Latch Data Hold Time Using Global Gate 0 0 ns tGOS Gate to Output (Note 2) tGWS Global Gate Width LOW (for LOW transparent) or HIGH (for HIGH transparent) tICO Input Register Clock to Combinatorial Output 19 22 11 MACH445-15/20 (Com’l) 6 12 8 20 ns ns ns 25 ns SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) (continued) -15 Parameter Symbol Parameter Description tICS Min Input Register Clock to Output Register Setup tWICL -20 Max Min Max Unit D-type 15 20 ns T-type 16 21 ns LOW 6 8 ns HIGH 6 8 ns 83.3 62.5 MHz Input Register Clock Width tWICH fMAXIR Maximum Input Register Frequency 1/(t WICL + t WICH ) tIGO Input Latch Gate to Combinatorial Output 20 25 ns tIGOL Input Latch Gate to Output Through Transparent Output Latch 22 27 ns tIGSA Input Latch Gate to Output Latch Setup Using Product Term Output Latch Gate 14 19 ns tIGSS Input Latch Gate to Output Latch Setup Using Global Output Latch Gate 16 21 ns tWIGL Input Latch Gate Width LOW 6 8 ns tAR Asynchronous Reset to Registered or Latched Output 20 25 ns tARW Asynchronous Reset Width (Note 3) 15 20 ns tARR Asynchronous Reset Recovery Time (Note 3) 15 20 ns tAP Asynchronous Preset to Registered or Latched Output 20 25 ns tAPW Asynchronous Preset Width (Note 3) 15 tAPR Asynchronous Preset Recovery Time (Note 3) 15 tEA Input, I/O, or Feedback to Output Enable (Note 2) 2 15 2 20 ns tER Input, I/O, or Feedback to Output 2 15 2 20 ns 22 ns Disable (Note 2) 20 ns 20 ns Input Register with Standard-Hold-Time Option tPDL Input, I/O, or Feedback to Output Through Transparent Input Latch tSIR Input Register Setup Time 2 2 ns tHIR Input Register Hold Time 4 5 ns tSIL Input Latch Setup Time 2 2 ns tHIL 17 Input Latch Hold Time 4 5 ns tSLLA Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Product Term Output Gate 10 12 ns tSLLS Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Output Gate 12 16 ns tPDLL Input, I/O, or Feedback to Output Through Transparent Input and Output Latches MACH445-15/20 (Com’l) 19 24 ns 15 SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 1) (continued) -15 Parameter Symbol Parameter Description Min -20 Max Min Max Unit 30 ns Input Register with Zero-Hold-Time Option tPDL ❙ Input, I/O, or Feedback to Output Through Transparent Input Latch tSIR❙ 23 Input Register Setup Time 6 8 ns ❙ Input Register Hold Time 0 0 ns ❙ Input Latch Setup Time 6 8 ns Input Latch Hold Time 0 0 ns Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Product Term Output Gate 16 20 ns tSLLS ❙ Setup Time from Input, I/O, or Feedback Through Transparent Input Latch to Output Gate 18 24 ns tPDLL ❙ Input, I/O, or Feedback to Output Through Transparent Input and Output Latches tHIR tSIL tHIL ❙ tSLLA ❙ 25 32 Notes: 1. See Switching Test Circuit at the end of this Data Book for test conditions. 2. Parameters measured with 32 outputs switching. 3. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified where frequency may be affected. 4. This parameter does not apply to flip-flops in the emulated mode since the feedback path is required for emulation. 16 MACH445-15/20 (Com’l) ns TYPICAL CURRENT VS. VOLTAGE (I-V) CHARACTERISTICS VCC = 5.0 V, TA = 25°C IOL (mA) 80 60 40 20 VOL (V) –1.0 –0.8 –0.6 –0.4 –0.2 –20 .2 .4 .6 .8 1.0 –40 –60 –80 17468E-4 Output, LOW IOH (mA) 25 1 2 3 4 5 VOH (V) –3 –2 –1 –25 –50 –75 –100 –125 –150 17468E-5 Output, HIGH II (mA) 20 VI (V) –2 –1 –20 1 2 3 4 5 –40 –60 –80 –100 Input MACH445-12/15/20 17468E-6 17 TYPICAL ICC CHARACTERISTICS VCC = 5 V, TA = 25°C 325 MACH445 300 275 250 225 200 175 ICC (mA) 150 125 100 75 50 25 0 0 10 20 30 40 50 60 70 Frequency (MHz) 17468E-7 The selected “typical” pattern is a 16-bit up/down counter. This pattern is programmed in each PAL block and is capable of being loaded, enabled, and reset. Maximum frequency shown uses internal feedback and a D-type register. 18 MACH445-12/15/20 TYPICAL THERMAL CHARACTERISTICS Measured at 25°C ambient. These parameters are not tested. Parameter Symbol Typ Parameter Description PQFP Unit θjc Thermal impedance, junction to case 5 °C/W θja Thermal impedance, junction to ambient 38 °C/W 200 lfpm air 32 °C/W 400 lfpm air 28 °C/W 600 lfpm air 26 °C/W 800 lfpm air 24 °C/W θjma Thermal impedance, junction to ambient with air flow Plastic θjc Considerations The data listed for plastic θjc are for reference only and are not recommended for use in calculating junction temperatures. The heat-flow paths in plastic-encapsulated devices are complex, making the θjc measurement relative to a specific location on the package surface. Tests indicate this measurement reference point is directly below the die-attach area on the bottom center of the package. Furthermore, θjc tests on packages are performed in a constant-temperature bath, keeping the package surface at a constant temperature. Therefore, the measurements can only be used in a similar environment. MACH445-12/15/20 19 SWITCHING WAVEFORMS Input, I/O, or Feedback VT tPD Combinatorial Output VT 17468E-8 Combinatorial Output Input, I/O, or Feedback Input, I/O, or Feedback VT tS VT tH tSL Gate VT Clock tHL tCO Registered Output VT tPDL tGO Latched Out VT VT 17468E-10 17468E-9 Registered Output Latched Output (MACH 2, 3, and 4) tWH Clock Gate VT tGWS tWL 17468E-12 17468E-11 Clock Width Gate Width (MACH 2, 3, and 4) Registered Input VT tSIR Input Register Clock Registered Input tHIR Input Register Clock VT tICO Combinatorial Output VT 17468E-13 Output Register Clock Registered Input (MACH 2 and 4) Notes: 1. VT = 1.5 V. 2. Input pulse amplitude 0 V to 3.0 V. 3. Input rise and fall times 2 ns–4 ns typical. 20 VT MACH445-12/15/20 VT tICS VT 17468E-14 Input Register to Output Register Setup (MACH 2 and 4) SWITCHING WAVEFORMS Latched In VT tSIL tHIL Gate VT tIGO Combinatorial Output VT 17468E-15 Latched Input (MACH 2 and 4) tPDLL Latched In VT Latched Out Input Latch Gate VT tIGOL tSLL tIGS VT Output Latch Gate 17468E-16 Latched Input and Output (MACH 2, 3, and 4) Notes: 1. VT = 1.5 V. 2. Input pulse amplitude 0 V to 3.0 V. 3. Input rise and fall times 2 ns–4 ns typical. MACH445-12/15/20 21 SWITCHING WAVEFORMS tWICH Clock Input Latch Gate VT VT tWICL tWIGL 17468E-18 17468E-17 Input Register Clock Width (MACH 2 and 4) Input Latch Gate Width (MACH 2 and 4) tARW tAPW Input, I/O, or Feedback Input, I/O, or Feedback VT VT tAR Registered Output tAP Registered Output VT VT tARR Clock tAPR Clock VT VT 17468E-19 17468E-20 Asynchronous Reset Asynchronous Preset Input, I/O, or Feedback VT tER Outputs tEA VOH - 0.5V VOL + 0.5V VT 17468E-21 Output Disable/Enable Notes: 1. VT = 1.5 V. 2. Input pulse amplitude 0 V to 3.0 V. 3. Input rise and fall times 2 ns–4 ns typical. 22 MACH445-12/15/20 KEY TO SWITCHING WAVEFORMS WAVEFORM INPUTS OUTPUTS Must be Steady Will be Steady May Change from H to L Will be Changing from H to L May Change from L to H Will be Changing from L to H Don’t Care, Any Change Permitted Changing, State Unknown Does Not Apply Center Line is HighImpedance “Off” State KS000010-PAL SWITCHING TEST CIRCUIT 5V S1 R1 Output Test Point R2 CL 17468E-22 Commercial Specification tPD, tCO tEA tER S1 CL R1 R2 Closed Measured Output Value 1.5 V Z → H: Open Z → L: Closed 35 pF H → Z: Open L → Z: Closed 5 pF 1.5 V 300 Ω 390 Ω H → Z: VOH – 0.5 V L → Z: VOL + 0.5 V *Switching several outputs simultaneously should be avoided for accurate measurement. MACH445-12/15/20 23 fMAX PARAMETERS The parameter fMAX is the maximum clock rate at which the device is guaranteed to operate. Because the flexibility inherent in programmable logic devices offers a choice of clocked flip-flop designs, fMAX is specified for three types of synchronous designs. The first type of design is a state machine with feedback signals sent off-chip. This external feedback could go back to the device inputs, or to a second device in a multi-chip state machine. The slowest path defining the period is the sum of the clock-to-output time and the input setup time for the external signals (tS + tCO). The reciprocal, fMAX, is the maximum frequency with external feedback or in conjunction with an equivalent speed device. This fMAX is designated “fMAX external.” The second type of design is a single-chip state machine with internal feedback only. In this case, flip-flop inputs are defined by the device inputs and flip-flop outputs. Under these conditions, the period is limited by the internal delay from the flip-flop outputs through the internal feedback and logic to the flip-flop inputs. This fMAX is designated “fMAX internal”. A simple internal counter is a good example of this type of design; therefore, this parameter is sometimes called “fCNT.” The third type of design is a simple data path application. In this case, input data is presented to the flip-flop and clocked through; no feedback is employed. Under these conditions, the period is limited by the sum of the data setup time and the data hold time (tS + tH). However, a lower limit for the period of each fMAX type is the minimum clock period (tWH + tWL). Usually, this minimum clock period determines the period for the third fMAX, designated “fMAX no feedback.” For devices with input registers, one additional fMAX parameter is specified: fMAXIR. Because this involves no feedback, it is calculated the same way as fMAX no feedback. The minimum period will be limited either by the sum of the setup and hold times (tSIR + tHIR) or the sum of the clock widths (tWICL + tWICH). The clock widths are normally the limiting parameters, so that fMAXIR is specified as 1/(tWICL + tWICH). Note that if both input and output registers are use in the same path, the overall frequency will be limited by tICS. All frequencies except fMAX internal are calculated from other measured AC parameters. fMAX internal is measured directly. CLK CLK (SECOND CHIP) LOGIC LOGIC REGISTER tS t CO tS fMAX Internal (fCNT) fMAX External; 1/(tS + tCO) LOGIC REGISTER CLK CLK REGISTER REGISTER tS tSIR fMAX No Feedback; 1/(tS + tH) or 1/(tWH + tWL) LOGIC tHIR fMAXIR ; 1/(tSIR + tHIR) or 1/(tWICL + tWICH) 17468E-23 24 MACH445-12/15/20 ENDURANCE CHARACTERISTICS The MACH families are manufactured using our advanced Electrically Erasable process. This technology uses an EE cell to replace the fuse link used in bipolar parts. As a result, the device can be erased and reprogrammed, a feature which allows 100% testing at the factory. Endurance Characteristics Parameter Symbol tDR N Parameter Description Min Units Test Conditions 10 Years Max Storage Temperature Min Pattern Data Retention Time 20 Years Max Operating Temperature Max Reprogramming Cycles 100 Cycles Normal Programming Conditions MACH445-12/15/20 25 INPUT/OUTPUT EQUIVALENT SCHEMATICS VCC 100 kΩ 1 kΩ VCC ESD Protection Input VCC VCC 100 kΩ 1 kΩ Preload Circuitry Feedback Input 17468E-24 I/O 26 MACH445-12/15/20 POWER-UP RESET The MACH devices have been designed with the capability to reset during system power-up. Following powerup, all flip-flops will be reset to LOW. The output state will depend on the logic polarity. This feature provides extra flexibility to the designer and is especially valuable in simplifying state machine initialization. A timing diagram and parameter table are shown below. Due to the synchronous operation of the power-up reset and the Parameter Symbol wide range of ways VCC can rise to its steady state, two conditions are required to insure a valid power-up reset. These conditions are: 1. The VCC rise must be monotonic. 2. Following reset, the clock input must not be driven from LOW to HIGH until all applicable input and feedback setup times are met. Parameter Descriptions Max Unit tPR Power-Up Reset Time 10 µs tS Input or Feedback Setup Time tWL Clock Width LOW See Switching Characteristics VCC Power 4V tPR Registered Output tS Clock tWL 17468E-25 Power-Up Reset Waveform MACH445-12/15/20 27 USING PRELOAD AND OBSERVABILITY In order to be testable, a circuit must be both controllable and observable. To achieve this, the MACH devices incorporate register preload and observability. Preloaded HIGH D In preload mode, each flip-flop in the MACH device can be loaded from the I/O pins, in order to perform functional testing of complex state machines. Register preload makes it possible to run a series of tests from a known starting state, or to load illegal states and test for proper recovery. This ability to control the MACH device’s internal state can shorten test sequences, since it is easier to reach the state of interest. Q1 Q AR Preloaded HIGH The observability function makes it possible to see the internal state of the buried registers during test by overriding each register’s output enable and activating the output buffer. The values stored in output and buried registers can then be observed on the I/O pins. Without this feature, a thorough functional test would be impossible for any designs with buried registers. D Q2 Q AR While the implementation of the testability features is fairly straightforward, care must be taken in certain instances to insure valid testing. One case involves asynchronous reset and preset. If the MACH registers drive asynchronous reset or preset lines and are preloaded in such a way that reset or preset are asserted, the reset or preset may remove the preloaded data. This is illustrated in Figure 2. Care should be taken when planning functional tests, so that states that will cause unexpected resets and presets are not preloaded. Another case to be aware of arises in testing combinatorial logic. When an output is configured as combinatorial, the observability feature forces the output into registered mode. When this happens, all product terms are forced to zero, which eliminates all combinatorial data. For a straight combinatorial output, the correct value will be restored after the preload or observe function, and there will be no problem. If the function implements a combinatorial latch, however, it relies on feedback to hold the correct value, as shown in Figure 3. As this value may change during the preload or observe operation, you cannot count on the data being correct after the operation. To insure valid testing in these cases, outputs that are combinatorial latches should not be tested immediately following a preload or observe sequence, but should first be restored to a known state. On Preload Mode Off Q1 AR Q2 Figure 2. Preload/Reset Conflict 17468E-26 Set All MACH 2 devices support both preload and observability. Contact individual programming vendors in order to verify programmer support. Reset Figure 3. Combinatorial Latch 17468E-27 28 MACH445-12/15/20