XC7336 36-Macrocell CMOS EPLD Product Specifications interconnected by the 100%-populated Universal Interconnect Matrix (UIM ). Features Ultra high-performance EPLD – 5 ns pin-to-pin speed on all fast inputs – 167 MHz maximum clock frequency Each Fast Function Block has 24 inputs and contains nine Macrocells configurable for registered or combinational logic. The nine Macrocell outputs feed back to the UIM and can simultaneously drive the output pads. • New low power XC7336Q • 100% routable with 100% utilization The UIM allows 100% connectivity between all function blocks and input pins, providing the ability to utilize 100% of the device while eliminating routing issues. • Incorporates four PAL-like 24V9 Fast Function Blocks • 36 Output Macrocells – Programmable I/O architecture – 24 mA drive The XC7336 is designed in 0.8 µ CMOS EPROM technology, in speed grades ranging from 5 to15 ns. The XC7336Q is also available now, providing lower power consumption in -10, -12 and -15 ns speed grades. • High-performance µP compatible • Peripheral Component Interface (PCI) compatible Device logic is automatically configured to the user’s specifications using the XEPLD software. The XEPLD software is capable of optimizing and collapsing logic. The SMARTswitch software/hardware feature allows implementation of buried combinatorial logic functions in the UIM, thus increasing device utilization. The XEPLD software supports third party schematic capture and HDL entry tools, as well as direct equation-based text files. Using a workstation or PC platform, designs are automatically mapped into the XC7336 in a matter of minutes. • JEDEC standard 3.3 V or 5 V I/O operation • Multiple security bits for design protection • 44-pin leaded chip carrier and 44-pin quad flat pack packages General Description The XC7336 is a member of the Xilinx XC7300 EPLD family. It consists of four PAL-like 24V9 Fast Function Blocks PQ44 PC44 22 28 I/FI 19 34 36 MC2-9 I/FO MC2-8 I/FO MC2-7 I/FO MC2-6 I/FO MC2-5 I/FO MC2-4 I/FO MC2-3 I/FO 29 30 33 34 35 36 37 38 39 23 24 27 28 29 30 31 32 33 40 43 44 1 2 3 4 5 6 34 37 38 39 40 41 42 43 44 FFB2 I/FO MC1-2 I/FO MC1-3 I/FO MC1-4 I/FO MC1-5 I/FO MC1-6 I/FO MC1-7 I/FO MC1-8 MC2-2 I/FO I/FO MC1-9 MC2-1 FO/FOE1 12 12 12 12 3 3 9 9 9 MC4-1 I/FO MC4-2 I/FO MC4-3 I/FO MC4-4 I/FO MC4-5 I/FO/FI MC4-6 I/FO/FI MC4-7 I/FO/FI I/FO 12 AND ARRAY I/FO UIM 12 FFB3 12 12 12 3 3 9 9 AND ARRAY 12 FFB4 27 26 25 24 22 20 19 18 17 42 MC1-1 9 21 20 19 18 16 14 13 12 11 I/FI I/FO/FI AND ARRAY 7 8 9 11 12 13 14 15 16 PQ44 12 FFB1 1 2 3 5 6 7 8 9 10 PC44 15 12 AND ARRAY • MC3-9 FO/FOE0 MC3-8 I/FO/FI MC3-7 I/FO/FI MC3-6 I/FO/FI/MR MC3-5 I/FO/FI MC3-4 I/FO/FI MC3-3 I/FO/FI MC4-8 MC3-2 FO/FCLK0 MC4-9 MC3-1 FO/FCLK1 9 9 X5452 Figure 1. XC7336 Functional Block Diagram 2-23 This document was created with FrameMaker 4 0 2 XC7336 CMOS EPLD Fast Function Blocks (FFB) The XC7336 provides four Fast Function Blocks which have 24 inputs that can be individually selected from the UIM, 12 fast input pins, or the 9 Macrocell feedbacks from the Function Block. The programmable AND array in each Fast Function Block generates 45 product terms to drive nine Macrocells in each FFB. Each Macrocell (Figure 2), can be configured for registered or combinatorial logic. Five product terms from the programmable AND array are allocated to each Macrocell. Four of these product terms are ORed together and may be optionally inverted before driving the input of a programmable D-type flip-flop. The fifth product term drives the asynchronous active-High programmable Reset or Set Input to the Macrocell flipflop. The flip-flop can be configured as a D-type or Toggle flip-flop or transparent for combinatorial outputs. The programmable clock source is one of two global FastCLK signals (FCLK0 or FCLK1) that are distributed with short delay and minimal skew over the entire chip. I/O Block The Fast Function Block Macrocells drive chip outputs directly through 3-state output buffers. Each output buffer can be individually controlled by one of two dedicated active-High Fast Output Enable inputs or permanently 2 Global Fast OE 2 12 from Fast Input Pins 12 24 Inputs from UIM enabled or disabled. The Macrocell output can also be routed back as an input to the Fast Function Block, and the UIM. Power-On Characteristics/Master Reset The XC7336 device undergoes a short internal initialization sequence upon device powerup. During this time (tRESET), the outputs remain 3-stated while the device is configured from its internal EPROM array and all registers are initialized. If the MR pin is tied to VCCINT, the initialization sequence is completely transparent to the user and is completed in tRESET after VCCINT has reached 4.75 V. If MR is held low while the device is powering up, the internal initialization sequence begins and outputs will remain 3-stated until the sequence is complete and MR is brought High. VCC rise must be monotonic to insure the initialization sequence is performed correctly. For additional flexibility, the MR pin is provided so the EPLD can be reinitialized after power is applied. On the falling edge of MR, all outputs become 3-stated and the initialization sequence is started. The outputs will remain 3-stated until the internal initialization sequence is complete and MR is brought High. The minimum MR pulse width is tWMR. If MR is brought High after tWMR, but before tRESET, the outputs will become active after tRESET. AND Array 3 Sum-of-Products from Previous Macrocell 9 from FFB Macrocell Feedback Fast Clocks 0 1 5 I/O Block 1 of 9 Macrocells OE Control 9 5 Private P-Terms per Macrocell 0 D/T Q 1 Output Polarity P-Term Assignment Control I/O Pin S/R Register Transparent Control Feedback to UIM Sum-of-Products to Succeeding Macrocell Pin Feedback to UIM X5218 Figure 2. Fast Function Block and Macrocell Schematic 2-24 Fast Function Block. Each UIM input can be programmed to connect to any UIM output. The delay through the interconnect matrix is constant. From Previous Macrocell Single-Product Term Assignment D/T When multiple inputs are programmed to be connected to the same output, this output produces the logical AND of the input signals. By choosing the appropriate signal polarities at the input pins, Macrocell outputs and Fast Function Block AND-array inputs, this AND logic can also be used to implement wide NAND, OR or NOR functions. This offers an additional level of logic without additional speed penalty. Q 4 Output Polarity 3.3 V or 5 V Interface Configuration Eight-Product Term Assignment The XC7336 can be used in systems with two different supply voltages: 3.3 V and 5 V. Each XC7336 device has separate VCC connections to the internal logic (VCCINT) and to the I/O pads (VCCIO). VCCINT must always be connected to a 5 V supply. VCCIO may be connected to either 3.3 V or 5 V, depending on the output interface requirement. S/R D/T Q 4 Output Polarity X3374 Figure 3. Fast Function Block Product Term Assignment Product Term Assignment Each Macrocell sum-of-product OR gate can be expanded using the Export product-term assignment feature. The Export function transfers product-terms in increments of four from one Macrocell to the neighboring Macrocell (Figure 3). Complex logic functions requiring up to 36 product-terms can be implemented using all nine Macrocells within the Fast Function Block. When productterms are assigned to adjacent Macrocells, the productterm normally dedicated to the Set or Reset function becomes the input to the Macrocell register. Universal Interconnect Matrix The UIM receives input from Macrocell outputs, I/O pins, and dedicated input pins. Acting as an unrestricted crossbar switch, the UIM generates 24 output signals to each 2-25 When VCCIO is connected to 5 V, the input thresholds are TTL levels, and thus compatible with 3.3 V and 5 V logic. The output High levels are also TTL compatible. When VCCIO is connected to 3.3 V, the input thresholds are still TTL levels, and the outputs pull up to the 3.3 V. This makes the XC7336 ideal for interfacing directly to 3.3 V components. In addition, the output structure is designed so that the I/O can also safely interface to a mixed 3.3 V and 5 V bus simultaneously. Low Power (Q) Devices The XC7336-10, -12 and -15 are available in a low power variant, designated the XC7336Q. Timing parameters for the XC7336 and the XC7336Q devices are identical. However, the XC7336Q features much lower power consumption. Using the XC7336Q will prove advantageous to any system design where power consumption and EM emissions are critical system parameters. XC7336 CMOS EPLD Power Management Design Security The XC7336 features a power-management scheme which permits non-speed-critical paths of a design to be operated at reduced power. Overall power dissipation is often reduced significantly, since, in most systems only a few paths are speed critical. The XC7336 has a multibit security system that controls access to the configuration programmed into the device. This security scheme uses multiple EPROM bits at various locations within the EPROM array to offer a higher degree of design security than other EPROM and fusedbased devices. Macrocells can individually be specified for high performance or low power operation by adding attributes to the logic schematic, or declaration statements to the behavioral description. To minimize power dissipation, unused Function Blocks are turned off and unused Macrocells in used Function Blocks are configured for low power operation. Operating current for each design can be approximated for specific operating conditions using the following equation: ICC(mA) = MCHP (4.3) + MCLP (3.5) + MC (0.005 mA/MHz) f XEPLD Translator Software For Q devices: (-10, -12, -15): ICC (mA) = MCHP (2.0) + MCLP (1.6) + MC (0.005 nA/MHz) f Macrocells in high-performance mode Macrocells in low-power mode Total number of Macrocells used Clock frequency (MHz) Figure 4 shows a typical power calculation for the XC7336 device, programmed as two 16-bit counters and operating at the indicated clock frequency. 200 ance High Perform Typical ICC (mA) 150 Low Power 100 ce rforman High Pe 50 0 Xilinx offers the HW-120 programmer for use during prototyping as well as support from major third party programmer companies. For production volumes, Xilinx and their licensed distributors offer factory programming of the XC7336 devices. For factory programming procedures, contact your local Xilinx representative. For non-Q devices: Where: MCHP = MCLP = MC = f = Prototyping and Programming s Q device er Low Pow 50 Clock Frequency (MHz) 100 X5767 Figure 4. Typical ICC vs Frequency for XC7336 2-26 The designer can create, implement, and verify digital logic circuits for EPLD devices using the Xilinx XEPLD software. Designs can be represented as schematics consisting of XEPLD library components, as behavioral descriptions (Boolean, HDL etc.), or as a combination of both techniques. The XEPLD translator automatically optimizes, collapses, and implements the design as well as writing a programming file without user intervention. At the completion of the compilation process, the XEPLD translator writes detailed report files for design analysis and documentation. Here are just a few of the XEPLD Development System features: • Automatic Optimization and Mapping Designs are automatically minimized and mapped into the devices for optimal efficiency and high performance. Critical logic functions are automatially assigned to special resources such as high speed clocks and global output enable signals. This allows the user to concentrate on design functionality without concern for physical implementation • Automatic use of UIM Resources – SMARTswitch The Universal Interconnect Maticx (UIM) used in Xilinx EPLDs provides an additional level of logic at no additional delay. XEPLD automatically uses the inherent logic capability of the UIM when possible to reduce Macrocell requirements and increase speed. • N-to-1 PAL Conversion Utility XEPLD automatically combines 20- and 24-pin standard PAL files into one top-level design file, checks for errors, and compiles the design into one or more EPLDs. The N-to-1 PAL converter is ideal for one step logic consolidation and board space reduction. • Complete Design Control Users have the option to override the automatic features of XEPLD and selectively control any or all device resources. • Multiple Platform Support XEPLD runs on IBM Compatible PCs, Sun, HP700, and IBM RS6000 platforms. Notice: The information contained in this data sheet pertains to products in the initial production phases of development. These specifications are subject to change without notice. Verify with your local Xilinx sales office that you have the latest data sheet before finalizing a design. Absolute Maximum Ratings Symbol Parameter Value Units VCC Supply voltage with respect to GND -0.5 to 7.0 V VIN DC Input voltage with respect to GND -0.5 to VCC +0.5 V VTS Voltage applied to 3-state output with respect to GND -0.5 to VCC +0.5 V TSTG Storage temperature -65 to +150 °C TSOL Maximum soldering temperature (10s @ 1/16 in. = 1.5 mm) +250 °C Warning: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those listed under Recommended Operating Conditions is not implied. Exposure to Absolute Maximum Ratings conditions for extended periods of time may affect device reliability. Recommended Operating Conditions Symbol Parameter Supply voltage relative to GND Min o Max Units TA = 0 C to 70 C 4.75 5.25 V TA = -40oC to 85oC 4.50 5.50 V 4.50 5.50 V I/O supply voltage relative to GND 3.0 3.60 V VIL Low-level input voltage 0 0.80 V VIH High-level input voltage 2.00 VO Output voltage 0 TIN Input signal transition time VCCINT/ VCCIO Supply voltage relative to GND VCCIO Supply voltage relative to GND Commercial o Industrial Military 2-27 TA = -55oC to TC = +125oC VCC +0.5 V VCCIO V 50 ns XC7336 CMOS EPLD DC Characteristics Over Recommended Operating Conditions Symbol Parameter Test Conditions Min Max Units 5 V TTL High-level output voltage IOH = -4.0 mA VCC = Min 2.4 V 3.3 V High-level output voltage IOH = -3.2 mA VCC = Min 2.4 V 5 V TTL Low-level output voltage IOL = 24 mA VCC = Min 0.5 V 3.3 V Low-level output voltage IOL = 24 mA VCC = Min 0.4 V IIL Input leakage current VCC = Max VIN = GND or VCCIO ± 10.0 µA IOZ Output high-Z leakage current VCC = Max VIN = GND or VCCIO ± 10.0 µA CIN Input capacitance for Input and I/O pins VIN = GND f = 1.0 MHz 6.0 pF CIN Input capacitance for global control pins (FCLK0, FCLK1, FOE0, FOE1) VIN = GND f = 1.0 MHz 8.0 pF COUT1 Output capacitance VIN = GND f = 1.0 MHz 10.0 pF ICC2 Supply current VOH VOL (Non-Q) (Q) VIN = VCC or GND VCCOUT = VCCCO= 5V f = 1.0 MHz @ 25°C 126 Typ mA 55 Typ Preliminary Power-up/Reset Timing Parameters Symbol Parameter tWMR Master Reset input Low pulse width tRESET Configuration completion time Notes: Min Typ Max 100 ns 80 1. Sample tested. 2. Measured with device programmed as two 16-bit counters. tWMR MR tRESET Hi-Z Output X5349 Figure 5. Global Reset Waveform 2-28 Units 160 µs Fast Function Block (FFB) External AC Characteristics3 XC7336-5 XC7336-7 XC7336-10 XC7336-12 XC7336-15 Min Min Min Min Min Symbol Parameter tPD tSU tH tCO tFOE tFOD fMAX tWLH Notes: Units Fast input to output valid 4 I/O or input to output valid 4 Fast input setup time before FCLK I/O or input setup time before FCLK Fast, I/O or input hold time after FCLK FCLK input to output valid FOE input to output valid FOE input to output disable Max count frequency 4 Fast Clock pulse width Max 5.0 8.5 Max 7.5 12.0 4.5 7.0 0 5.0 8.5 0 4.5 7.0 7.0 167.0 3.0 Max 10.0 15.0 5.0 10.0 0 12.0 19.0 6.0 13.0 0 4.5 7.5 7.5 125.0 4.0 Max 8.0 10.0 10.0 100.0 5.0 15.0 23.0 7.0 15.0 0 9.0 12.0 12.0 80.0 5.5 12.0 15.0 15.0 66.7 6.0 3. All appropriate ac specifications tested using Figure 7 as test load circuit. 4. Assumes four product terms per output. Fast Input tSU FOE Pin tH tFOD tFOE FCLK Output tCO Output Input or I/O tSU tH tWH FCLK FCLK tCO tWL Output X5695 Figure 6. Switching Waveforms VTEST R1 Device Output Test Point CL R2 Device Input Rise and Fall Times < 3ns VCCIO Level VTEST R1 R2 CL 5V 5.0 V 160 Ω 120 Ω 35 pF 3.3 V 3.3 V 260 Ω 360 Ω 35 pF X5222 Figure 7. AC Load Circuit 2-29 Max ns ns ns ns ns ns ns ns MHz ns XC7336 CMOS EPLD tFOE FOE FAST INPUT tIN I, I/O tIN Fast Function Block UIM Delay tFSUI tFCOI tFPDI tFHI tFAOI FFB Logic tFLOGI tUIM P-Term Assignment tPTXI FFB Feedback tFFD FCLK tFOUT Pin tFCLKI X5221 Figure 8. XC7336 Timing Model Timing Model The timing model is based on the fixed internal delays of the XC7336 architecture which consists of three basic parts: I/O Blocks, the UIM and Fast Function Blocks. The timing model identifies the internal delay paths and their relationships to ac characteristics. Using this model and the ac characteristics, designers can easily calculate the timing information for the XC7336. Timing within the XC7336 is accurately determined using external timing parameters from the device data sheet, using a variety of CAE simulators, or with the timing model shown in Figure 8. Fast Function Block (FFB) Internal AC Characteristics Symbol Parameter tFLOGI XC7336-5 XC7336-7 XC7336-10 XC7336-12 XC7336-15 Min Min Min Min Min FFB logic array delay 5 tFLOGILP Low-power FFB logic array delay 5 Max Max Max Max Max Units 1.0 1.5 1.5 2.0 2.0 ns 2.0 3.5 5.5 7.0 8.0 ns tFSUI FFB register setup time 2.5 1.5 2.5 3.0 4.0 ns tFHI FFB register hold time 1.0 2.5 2.5 3.0 3.0 ns tFCOI FFB register clock-to-output delay 1.0 1.0 1.0 1.0 1.0 ns tFPDI FFB register pass through delay 0.5 0.5 0.5 1.0 1.0 ns tFAOI FFB register async. set delay 2.0 2.0 2.5 3.0 4.0 ns tPTXI FFB p-term assignment delay 0.6 0.8 1.0 1.2 1.5 ns tFFD FFB feedback delay 0.5 4.0 5.0 6.5 8.0 ns Notes: 5. Specifications account for logic paths that use the maximum number of available product terms for a given Macrocell. Internal AC Characteristics Symbol Parameter XC7336-5 XC7336-7 XC7336-10 XC7336-12 XC7336-15 Min Min Min Min Min Max Max Max Max Max Units tIN Input pad and buffer delay 1.5 2.5 3.5 4.0 5.0 ns tFOUT FFB output buffer and pad delay 2.0 3.0 4.5 5.0 7.0 ns tUIM Universal Interconnect Matrix delay 3.5 4.5 5.0 7.0 8.0 ns tFCLKI Fast clock buffer delay 1.5 1.5 2.5 3.0 4.0 ns 2-30 Combinatorial Switching Characteristics tIN Input, I/O Pin tUIM UIM Delay tLOGI tFLOGI Logic Delay tPTXI P-Term Assignment Delay tPDI tFPDI Transparent Register Delay tOUT tFOUT Output Buffer Output Pin X3339 Asynchronous Clock Switching Characteristics tPCW tPCW Input, I/O Pin tIN Input, I/O Delay tUIM UIM Delay tLOGI Clock at Register tSUI tHI Data from Logic Array tCOI tUIM tAOI tUIM Register to UIM tOUT tOUT Register to Output Pin X3580 2-31 XC7336 CMOS EPLD Synchronous Clock Switching Characteristics tCWF tCWF FCLK Pin tSUIN tSUCEIN tHIN tHCEIN Data/CE at Input I/O Register tCOIN tUIM Input, I/O Register to UIM tFCLKI Fast Clock Input Delay tIN tUIM Data at Input I/O Pin tLOGI tFLOGI tSUI tFSUI tHI tFHI Data at Input Register tCOI tFCOI tOUT tFOUT Register to Output Pin X3494 XC7336 Pinouts PQ44 PC44 Input XC7336 Output PQ44 PC44 39 40 41 42 43 44 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 I/FO/FI I/FO/FI I/FO/FI I/FO/FI FO/FCLK0 FO/FCLK1 I/FO/FI I/FO I/FO MR MC3-6 MC3-5 MC3-4 MC3-3 MC3-2 MC3-1 MC1-1 MC1-2 MC1-3 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 GND I/FO I/FO I/FO I/FO I/FO I/FO I/FO I/FO/FI I/FO/FI I/FO/FI MC1-4 MC1-5 MC1-6 MC1-7 MC1-8 MC1-9 MC4-9 MC4-8 MC4-7 MC4-6 VCCINT I/FO MC4-5 2-32 Input XC7336 Output GND I/FO I/FO I/FO I/FO I/FI I/FO I/FO MC4-4 MC4-3 MC4-2 MC4-1 MC2-9 MC2-8 GND VCCIO I/FO I/FO I/FO I/FO I/FO I/FO FO/FOE1 FO/FOE0 MC2-7 MC2-6 MC2-5 MC2-4 MC2-3 MC2-2 MC2-1 MC3-9 VCCINT/VPP I/FI I/FO/FI I/FO/FI MC3-8 MC3-7 Ordering Information XC7336 - 5 PC 44 C Device Type Temperature Range Power Option Speed Number of Pins Package Type Power Options Q Low Power -10, -12, -15 speeds Speed Options -15 15 ns pin-to-pin delay -12 12 ns pin-to-pin delay -10 10 ns pin-to-pin delay -7 7.5 ns pin-to-pin delay (commercial only) -5 5 ns pin-to-pin delay (commercial only) Packaging Options PC44 44-Pin Plastic Leaded Chip Carrier WC44 44-Pin Windowed Ceramic Leaded Chip Carrier PQ44 44-Pin Plastic Quad Flat Pack Temperature Options C Commercial I Industrial 0oC to70oC -40oC to 85oC Component Availability Pins 44 Type Plastic Ceramic Plastic PLCC CLCC PQFP Plastic PLCC PC44 WC44 PQ44 PC68 CI CI CI C C CI CI CI C C C C C C C Code -15 -12 XC7336 -10 -7 -5 68 C = Commercial = 0° to +70°C Ceramic Plastic Ceramic CLCC PLCC CLCC WC68 PC84 I = Industrial = -40° to 85°C WC84 144 160 225 Plastic Ceramic PQFP PGA Plastic PQFP Plastic Windowed BGA BGA PQ100 PQ160 BG225 PG144 WB225 X5650 The Programmable Logic Company 100 84 SM 2-33 XC7336 CMOS EPLD 2-34