CY37192P160-125AC

Ultra37000 CPLD Family 5V, 3.3V, ISR™ High-Performance CPLDs Features General Description • In-System Reprogrammable™ (ISR™) CMOS CPLDs — JTAG interface for reconfigurability — Design changes do not cause pinout changes — Design changes do not cause timing changes • High density — 32 to 512 macrocells — 32 to 264 I/O pins — Five dedicated inputs including four clock pins • Simple timing model — No fanout delays — No expander delays — No dedicated vs. I/O pin delays — No additional delay through PIM — No penalty for using full 16 product terms — No delay for steering or sharing product terms • 3.3V and 5V versions • PCI-compatible[1] • Programmable bus-hold capabilities on all I/Os • Intelligent product term allocator provides: — 0 to 16 product terms to any macrocell — Product term steering on an individual basis — Product term sharing among local macrocells • Flexible clocking — Four synchronous clocks per device — Product term clocking — Clock polarity control per logic block • Consistent package/pinout offering across all densities The Ultra37000™ family of CMOS CPLDs provides a range of high-density programmable logic solutions with unparalleled system performance. The Ultra37000 family is designed to bring the flexibility, ease of use, and performance of the 22V10 to high-density CPLDs. The architecture is based on a number of logic blocks that are connected by a Programmable Interconnect Matrix (PIM). Each logic block features its own product term array, product term allocator, and 16 macrocells. The PIM distributes signals from the logic block outputs and all input pins to the logic block inputs. All of the Ultra37000 devices are electrically erasable and In-System Reprogrammable (ISR), which simplifies both design and manufacturing flows, thereby reducing costs. The ISR feature provides the ability to reconfigure the devices without having design changes cause pinout or timing changes. The Cypress ISR function is implemented through a JTAG-compliant serial interface. Data is shifted in and out through the TDI and TDO pins, respectively. Because of the superior routability and simple timing model of the Ultra37000 devices, ISR allows users to change existing logic designs while simultaneously fixing pinout assignments and maintaining system performance. The entire family features JTAG for ISR and boundary scan, and is compatible with the PCI Local Bus specification, meeting the electrical and timing requirements. The Ultra37000 family features user programmable bus-hold capabilities on all I/Os. Ultra37000 5.0V Devices The Ultra37000 devices operate with a 5V supply and can support 5V or 3.3V I/O levels. VCCO connections provide the capability of interfacing to either a 5V or 3.3V bus. By connecting the VCCO pins to 5V the user insures 5V TTL levels on the outputs. If VCCO is connected to 3.3V the output levels meet 3.3V JEDEC standard CMOS levels and are 5V tolerant. These devices require 5V ISR programming. — Simplifies design migration Ultra37000V 3.3V Devices — Same pinout for 3.3V and 5.0V devices Devices operating with a 3.3V supply require 3.3V on all VCCO pins, reducing the device’s power consumption. These devices support 3.3V JEDEC standard CMOS output levels, and are 5V-tolerant. These devices allow 3.3V ISR programming. • Packages — 44 to 400 leads in PLCC, CLCC, PQFP, TQFP, CQFP, BGA, and Fine-Pitch BGA packages — Lead (Pb)-free packages available Note: 1. Due to the 5V-tolerant nature of 3.3V device I/Os, the I/Os are not clamped to VCC, PCI VIH = 2V. Cypress Semiconductor Corporation Document #: 38-03007 Rev. *E • 3901 North First Street • San Jose, CA 95134 • 408-943-2600 Revised March 7, 2004 Ultra37000 CPLD Family Selection Guide 5.0V Selection Guide General Information Speed (tPD) I/O Pins Speed (fMAX) Device Macrocells Dedicated Inputs CY37032 32 5 32 6 200 CY37064 64 5 32/64 6 200 CY37128 128 5 64/128 6.5 167 CY37192 192 5 120 7.5 154 CY37256 256 5 128/160/192 7.5 154 CY37384 384 5 160/192 10 118 CY37512 512 5 160/192/264 10 118 Speed Bins Device 200 167 CY37032 X X X CY37064 X X X CY37128 154 143 125 X 100 X 83 66 X CY37192 X X X CY37256 X X X CY37384 X X CY37512 X X X Device-Package Offering and I/O Count Device 44Lead TQFP 44Lead PLCC CY37032 37 37 CY37064 37 37 44Lead CLCC 84Lead PLCC 37 69 CY37128 84Lead CLCC 100Lead TQFP 160Lead TQFP 160Lead CQFP 208Lead PQFP 133 208Lead CQFP 292Lead PBGA 388Lead PBGA 69 69 69 69 133 CY37192 125 CY37256 133 165 197 CY37384 165 197 CY37512 165 165 197 269 3.3V Selection Guide General Information Device Macrocells Dedicated Inputs I/O Pins Speed (tPD) Speed (fMAX) CY37032V 32 5 32 8.5 143 CY37064V 64 5 32/64 8.5 143 CY37128V 128 5 64/80/128 10 125 CY37192V 192 5 120 12 100 CY37256V 256 5 128/160/192 12 100 CY37384V 384 5 160/192 15 83 CY37512V 512 5 160/192/264 15 83 Document #: 38-03007 Rev. *E Page 2 of 64 Ultra37000 CPLD Family Speed Bins Device 200 167 154 143 CY37032V X CY37064V X 125 100 83 66 X X CY37128V X X CY37192V X X CY37256V X X CY37384V X X CY37512V X X CY37032V 37 CY37064V 37 400Lead FBGA Device 44Lead TQFP 44Lead CLCC 48Lead FBGA 84Lead CLCC 100Lead TQFP 100Lead FBGA 160Lead TQFP 160Lead CQFP 208Lead PQFP 208Lead CQFP 292Lead PBGA 256Lead FBGA 388Lead PBGA Device-Package Offering and I/O Count 37 37 37 CY37128V 69 69 69 69 85 133 CY37192V 125 CY37256V 133 165 197 CY37384V 165 197 CY37512V 165 Architecture Overview of Ultra37000 Family Programmable Interconnect Matrix The PIM consists of a completely global routing matrix for signals from I/O pins and feedbacks from the logic blocks. The PIM provides extremely robust interconnection to avoid fitting and density limitations. The inputs to the PIM consist of all I/O and dedicated input pins and all macrocell feedbacks from within the logic blocks. The number of PIM inputs increases with pin count and the number of logic blocks. The outputs from the PIM are signals routed to the appropriate logic blocks. Each logic block receives 36 inputs from the PIM and their complements, allowing for 32-bit operations to be implemented in a single pass through the device. The wide number of inputs to the logic block also improves the routing capacity of the Ultra37000 family. An important feature of the PIM is its simple timing. The propagation delay through the PIM is accounted for in the timing specifications for each device. There is no additional delay for traveling through the PIM. In fact, all inputs travel through the PIM. As a result, there are no route-dependent timing parameters on the Ultra37000 devices. The worst-case PIM delays are incorporated in all appropriate Ultra37000 specifications. Routing signals through the PIM is completely invisible to the user. All routing is accomplished by software—no hand routing is necessary. Warp® and third-party development packages automatically route designs for the Ultra37000 family in a matter of minutes. Finally, the rich routing resources of the Ultra37000 family accommodate last minute logic changes while maintaining fixed pin assignments. Document #: 38-03007 Rev. *E 133 165 197 197 269 269 Logic Block The logic block is the basic building block of the Ultra37000 architecture. It consists of a product term array, an intelligent product-term allocator, 16 macrocells, and a number of I/O cells. The number of I/O cells varies depending on the device used. Refer to Figure 1 for the block diagram. Product Term Array Each logic block features a 72 x 87 programmable product term array. This array accepts 36 inputs from the PIM, which originate from macrocell feedbacks and device pins. Active LOW and active HIGH versions of each of these inputs are generated to create the full 72-input field. The 87 product terms in the array can be created from any of the 72 inputs. Of the 87 product terms, 80 are for general-purpose use for the 16 macrocells in the logic block. Four of the remaining seven product terms in the logic block are output enable (OE) product terms. Each of the OE product terms controls up to eight of the 16 macrocells and is selectable on an individual macrocell basis. In other words, each I/O cell can select between one of two OE product terms to control the output buffer. The first two of these four OE product terms are available to the upper half of the I/O macrocells in a logic block. The other two OE product terms are available to the lower half of the I/O macrocells in a logic block. The next two product terms in each logic block are dedicated asynchronous set and asynchronous reset product terms. The final product term is the product term clock. The set, reset, OE and product term clock have polarity control to realize OR functions in a single pass through the array. Page 3 of 64 Ultra37000 CPLD Family 2 3 0−16 PRODUCT TERMS 7 0−16 PRODUCT TERMS FROM PIM 36 72 x 87 PRODUCT TERM ARRAY 80 MACROCELL 1 I/O CELL 0 to cells 2, 4, 6 8, 10, 12 PRODUCT TERM ALLOCATOR 0−16 PRODUCT TERMS 0−16 TO PIM MACROCELL 0 2 16 PRODUCT TERMS MACROCELL 14 I/O CELL 14 MACROCELL 15 8 Figure 1. Logic Block with 50% Buried Macrocells Low-Power Option Each logic block can operate in high-speed mode for critical path performance, or in low-power mode for power conservation. The logic block mode is set by the user on a logic block by logic block basis. Product Term Allocator Through the product term allocator, software automatically distributes product terms among the 16 macrocells in the logic block as needed. A total of 80 product terms are available from the local product term array. The product term allocator provides two important capabilities without affecting performance: product term steering and product term sharing. Product Term Steering Product term steering is the process of assigning product terms to macrocells as needed. For example, if one macrocell requires ten product terms while another needs just three, the product term allocator will “steer” ten product terms to one macrocell and three to the other. On Ultra37000 devices, product terms are steered on an individual basis. Any number between 0 and 16 product terms can be steered to any macrocell. Note that 0 product terms is useful in cases where a particular macrocell is unused or used as an input register. Product Term Sharing Product term sharing is the process of using the same product term among multiple macrocells. For example, if more than one output has one or more product terms in its equation that are common to other outputs, those product terms are only programmed once. The Ultra37000 product term allocator allows sharing across groups of four output macrocells in a Document #: 38-03007 Rev. *E variable fashion. The software automatically takes advantage of this capability—the user does not have to intervene. Note that neither product term sharing nor product term steering have any effect on the speed of the product. All worst-case steering and sharing configurations have been incorporated in the timing specifications for the Ultra37000 devices. Ultra37000 Macrocell Within each logic block there are 16 macrocells. Macrocells can either be I/O Macrocells, which include an I/O Cell which is associated with an I/O pin, or buried Macrocells, which do not connect to an I/O. The combination of I/O Macrocells and buried Macrocells varies from device to device. Buried Macrocell Figure 2 displays the architecture of buried macrocells. The buried macrocell features a register that can be configured as combinatorial, a D flip-flop, a T flip-flop, or a level-triggered latch. The register can be asynchronously set or asynchronously reset at the logic block level with the separate set and reset product terms. Each of these product terms features programmable polarity. This allows the registers to be set or reset based on an AND expression or an OR expression. Clocking of the register is very flexible. Four global synchronous clocks and a product term clock are available to clock the register. Furthermore, each clock features programmable polarity so that registers can be triggered on falling as well as rising edges (see the Clocking section). Clock polarity is chosen at the logic block level. Page 4 of 64 Ultra37000 CPLD Family Bus Hold Capabilities on all I/Os The buried macrocell also supports input register capability. The buried macrocell can be configured to act as an input register (D-type or latch) whose input comes from the I/O pin associated with the neighboring macrocell. The output of all buried macrocells is sent directly to the PIM regardless of its configuration. Bus-hold, which is an improved version of the popular internal pull-up resistor, is a weak latch connected to the pin that does not degrade the device’s performance. As a latch, bus-hold maintains the last state of a pin when the pin is placed in a high-impedance state, thus reducing system noise in bus-interface applications. Bus-hold additionally allows unused device pins to remain unconnected on the board, which is particularly useful during prototyping as designers can route new signals to the device without cutting trace connections to VCC or GND. For more information, see the application note Understanding Bus-Hold—A Feature of Cypress CPLDs. I/O Macrocell Figure 2 illustrates the architecture of the I/O macrocell. The I/O macrocell supports the same functions as the buried macrocell with the addition of I/O capability. At the output of the macrocell, a polarity control mux is available to select active LOW or active HIGH signals. This has the added advantage of allowing significant logic reduction to occur in many applications. Programmable Slew Rate Control Each output has a programmable configuration bit, which sets the output slew rate to fast or slow. For designs concerned with meeting FCC emissions standards the slow edge provides for lower system noise. For designs requiring very high performance the fast edge rate provides maximum system performance. The Ultra37000 macrocell features a feedback path to the PIM separate from the I/O pin input path. This means that if the macrocell is buried (fed back internally only), the associated I/O pin can still be used as an input. I/O MACROCELL FROM PTM FAST 0 1 0−16 PRODUCT TERMS SLEW SLOW C25 P D/T/L 0 1 2 3 C26 0 O O 0 1 Q 1 R 4 C4 DECODE C0 C1 C24 I/O CELL O “0” “1” 0 1 2 3 O C6 C5 1 0 C2 C3 BURIED MACROCELL FROM PTM 0−16 0 1 PRODUCT TERMS C25 0 0 0 1 2 3 O 1 P D/T/L C7 Q R 4 C0 C1 C24 O 1 Q DECODE 1 0 C2 C3 FEEDBACK TO PIM FEEDBACK TO PIM FEEDBACK TO PIM ASYNCHRONOUS BLOCK RESET 4 SYNCHRONOUS CLOCKS (CLK0,CLK1,CLK2,CLK3) ASYNCHRONOUS 1 ASYNCHRONOUS CLOCK(PTCLK) BLOCK PRESET OE0 OE1 Figure 2. I/O and Buried Macrocells Document #: 38-03007 Rev. *E Page 5 of 64 Ultra37000 CPLD Family INPUT PIN D 0 1 2 3 FROM CLOCK POLARITY MUXES D Q 0 1 2 3 Q O TO PIM O C12 C13 C10 C11 D Q LE Figure 3. Input Macrocell 0 TO CLOCK MUX ON ALL INPUT MACROCELLS O 1 INPUT/CLOCK PIN C12 0 O 1 FROM CLOCK POLARITY INPUT CLOCK PINS D 0 1 2 3 Q D Q C13, C14, C15 0 1 2 3 O TO PIM O TO CLOCK MUX IN EACH LOGIC BLOCK OR C16 CLOCK POLARITY MUX ONE PER LOGIC BLOCK FOR EACH CLOCK INPUT C10C11 C8 C9 D Q LE Figure 4. Input/Clock Macrocell Clocking Timing Model Each I/O and buried macrocell has access to four synchronous clocks (CLK0, CLK1, CLK2 and CLK3) as well as an asynchronous product term clock PTCLK. Each input macrocell has access to all four synchronous clocks. One of the most important features of the Ultra37000 family is the simplicity of its timing. All delays are worst case and system performance is unaffected by the features used. Figure 5 illustrates the true timing model for the 167-MHz devices in high speed mode. For combinatorial paths, any input to any output incurs a 6.5-ns worst-case delay regardless of the amount of logic used. For synchronous systems, the input set-up time to the output macrocells for any input is 3.5 ns and the clock to output time is also 4.0 ns. These measurements are for any output and synchronous clock, regardless of the logic used. Dedicated Inputs/Clocks Five pins on each member of the Ultra37000 family are designated as input-only. There are two types of dedicated inputs on Ultra37000 devices: input pins and input/clock pins. Figure 3 illustrates the architecture for input pins. Four input options are available for the user: combinatorial, registered, double-registered, or latched. If a registered or latched option is selected, any one of the input clocks can be selected for control. Figure 4 illustrates the architecture for the input/clock pins. Like the input pins, input/clock pins can be combinatorial, registered, double-registered, or latched. In addition, these pins feed the clocking structures throughout the device. The clock path at the input has user-configurable polarity. Product Term Clocking In addition to the four synchronous clocks, the Ultra37000 family also has a product term clock for asynchronous clocking. Each logic block has an independent product term clock which is available to all 16 macrocells. Each product term clock also supports user configurable polarity selection. Document #: 38-03007 Rev. *E The Ultra37000 features: • No fanout delays • No expander delays • No dedicated vs. I/O pin delays • No additional delay through PIM • No penalty for using 0–16 product terms • No added delay for steering product terms • No added delay for sharing product terms • No routing delays • No output bypass delays The simple timing model of the Ultra37000 family eliminates unexpected performance penalties. Page 6 of 64 Ultra37000 CPLD Family resources for pinout flexibility, and a simple timing model for consistent system performance. COMBINATORIAL SIGNAL tPD = 6.5 ns INPUT OUTPUT Warp REGISTERED SIGNAL tS = 3.5 ns D,T,L O tCO = 4.5 ns INPUT OUTPUT CLOCK Figure 5. Timing Model for CY37128 JTAG and PCI Standards 5V operation of the Ultra37000 is fully compliant with the PCI Local Bus Specification published by the PCI Special Interest Group. The 3.3V products meet all PCI requirements except for the output 3.3V clamp, which is in direct conflict with 5V tolerance. The Ultra37000 family’s simple and predictable timing model ensures compliance with the PCI AC specifications independent of the design. IEEE 1149.1-compliant JTAG The Ultra37000 family has an IEEE 1149.1 JTAG interface for both Boundary Scan and ISR. Boundary Scan The Ultra37000 family supports Bypass, Sample/Preload, Extest, Idcode, and Usercode boundary scan instructions. The JTAG interface is shown in Figure 6. TCK TDO JTAG TAP CONTROLLER Bypass Reg. Boundary Scan idcode Usercode ISR Prog. Data Registers Figure 6. JTAG Interface In-System Reprogramming (ISR) In-System Reprogramming is the combination of the capability to program or reprogram a device on-board, and the ability to support design changes without changing the system timing or device pinout. This combination means design changes during debug or field upgrades do not cause board respins. The Ultra37000 family implements ISR by providing a JTAG compliant interface for on-board programming, robust routing Document #: 38-03007 Rev. *E Warp Professional contains several additional features. It provides an extra method of design entry with its graphical block diagram editor. It allows up to 5 ms timing simulation instead of only 2 ms. It allows comparison of waveforms before and after design changes. Warp Enterprise™ Warp Enterprise provides even more features. It provides unlimited timing simulation and source-level behavioral simulation as well as a debugger. It has the ability to generate graphical HDL blocks from HDL text. It can even generate testbenches. Warp is available for PC and UNIX platforms. Some features are not available in the UNIX version. For further information see the Warp for PC, Warp for UNIX, Warp Professional and Warp Enterprise data sheets on Cypress’s web site (www.cypress.com). Third-Party Software Instruction Register TMS Warp is a state-of-the-art compiler and complete CPLD design tool. For design entry, Warp provides an IEEE-STD-1076/1164 VHDL text editor, an IEEE-STD-1364 Verilog text editor, and a graphical finite state machine editor. It provides optimized synthesis and fitting by replacing basic circuits with ones pre-optimized for the target device, by implementing logic in unused memory and by perfect communication between fitting and synthesis. To facilitate design and debugging, Warp provides graphical timing simulation and analysis. Warp Professional™ PCI Compliance TDI Development Software Support Although Warp is a complete CPLD development tool on its own, it interfaces with nearly every third party EDA tool. All major third-party software vendors provide support for the Ultra37000 family of devices. Refer to the third-party software data sheet or contact your local sales office for a list of currently supported third-party vendors. Programming There are four programming options available for Ultra37000 devices. The first method is to use a PC with the 37000 UltraISR programming cable and software. With this method, the ISR pins of the Ultra37000 devices are routed to a connector at the edge of the printed circuit board. The 37000 UltraISR programming cable is then connected between the parallel port of the PC and this connector. A simple configuration file instructs the ISR software of the programming operations to be performed on each of the Ultra37000 devices in the system. The ISR software then automatically completes all of the necessary data manipulations required to accomplish the programming, reading, verifying, and other ISR functions. For more information on the Cypress ISR Interface, see the ISR Programming Kit data sheet (CY3700i). The second method for programming Ultra37000 devices is on automatic test equipment (ATE). This is accomplished through a file created by the ISR software. Check the Cypress website for the latest ISR software download information. Page 7 of 64 Ultra37000 CPLD Family The third programming option for Ultra37000 devices is to utilize the embedded controller or processor that already exists in the system. The Ultra37000 ISR software assists in this method by converting the device JEDEC maps into the ISR serial stream that contains the ISR instruction information and the addresses and data of locations to be programmed. The embedded controller then simply directs this ISR stream to the chain of Ultra37000 devices to complete the desired reconfiguring or diagnostic operations. Contact your local sales office for information on availability of this option. Document #: 38-03007 Rev. *E The fourth method for programming Ultra37000 devices is to use the same programmer that is currently being used to program FLASH370i devices. For all pinout, electrical, and timing requirements, refer to device data sheets. For ISR cable and software specifications, refer to the UltraISR kit data sheet (CY3700i). Third-Party Programmers As with development software, Cypress support is available on a wide variety of third-party programmers. All major third-party programmers (including BP Micro, Data I/O, and SMS) support the Ultra37000 family. Page 8 of 64 Ultra37000 CPLD Family Logic Block Diagrams CY37032/CY37032V Clock/ Input Input 1 TDI TCK TMS 4 36 LOGIC BLOCK A 16 I/Os I/O0−I/O15 36 PIM 16 16 16 LOGIC BLOCK B Input Clock/ Input 4 1 4 4 I/O0-I/O15 LOGIC BLOCK A LOGIC BLOCK B I/O16-I/O31 32 TDI TCK TMS JTAG Tap Controller Document #: 38-03007 Rev. *E 36 36 16 16 36 16 I/Os 16 I/Os I/O16−I/O31 16 CY37064/CY37064V 16 I/Os TDO JTAGEN 4 4 JTAG Tap Controller 16 PIM LOGIC BLOCK D 16 I/Os LOGIC BLOCK C 16 I/Os I/O48-I/O63 36 16 I/O32-I/O47 32 TDO Page 9 of 64 Ultra37000 CPLD Family Logic Block Diagrams (continued) TDI CY37128/CY37128V CLOCK INPUTS INPUTS 1 4 I/O16–I/O31 I/O32–I/O47 I/O28–I/O63 16 I/Os LOGIC BLOCK 36 A 16 I/Os LOGIC BLOCK B 16 I/Os LOGIC BLOCK C 16 I/Os 36 PIM 16 LOGIC BLOCK D 36 36 16 16 36 36 16 16 36 36 16 16 16 I/Os LOGIC BLOCK 16 I/Os LOGIC BLOCK 16 I/Os LOGIC BLOCK 16 I/Os G I/O112–I/O127 I/O96–I/O111 I/O80–I/O95 F I/O64–I/O79 64 CY37192/CY37192V Input 1 Clock/ Input 4 4 4 JTAG Tap Controller LOGIC BLOCK E TDO JTAGEN H 16 64 TDI TCK TMS Controller TMS 4 INPUT/CLOCK MACROCELLS 4 INPUT MACROCELL I/O0–I/O15 JTAG Tap TCK 10 I/Os I/O0–I/O9 LOGIC BLOCK A 10 I/Os I/O10–I/O19 LOGIC BLOCK B 10 I/Os I/O20–I/O29 LOGIC BLOCK C 10 I/Os I/O30–I/O39 LOGIC BLOCK D 10 I/Os I/O40–I/O49 LOGIC BLOCK E 10 I/Os I/O50–I/O59 LOGIC BLOCK F 60 36 36 16 16 36 36 16 16 36 36 16 16 36 16 PIM 36 16 36 36 16 16 36 36 16 16 LOGIC BLOCK L 10 I/Os I/O110–I/O119 LOGIC BLOCK K 10 I/Os I/O100–I/O109 LOGIC BLOCK J 10 I/Os I/O90–I/O99 LOGIC BLOCK I 10 I/Os I/O80–I/O89 LOGIC BLOCK H 10 I/Os I/O70–I/O79 LOGIC BLOCK G 10 I/Os I/O60–I/O69 60 TDO Document #: 38-03007 Rev. *E Page 10 of 64 Ultra37000 CPLD Family Logic Block Diagrams (continued) Clock/ Input Input CY37256/CY37256V 1 4 4 4 12 I/Os I/O0−I/O11 LOGIC BLOCK A 12 I/Os I/O12−I/O23 LOGIC BLOCK B 12 I/Os I/O24−I/O35 LOGIC BLOCK C 12 I/Os I/O36−I/O47 LOGIC BLOCK D 12 I/Os I/O48−I/O59 LOGIC BLOCK E 12 I/Os I/O60−I/O71 LOGIC BLOCK F 12 I/Os I/O72−I/O83 LOGIC BLOCK G 12 I/Os LOGIC BLOCK H I/O84−I/O95 TDI TCK TMS JTAG Tap Controller Document #: 38-03007 Rev. *E TDO 96 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 PIM 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 LOGIC BLOCK P 12 I/Os I/O180−I/O191 LOGIC BLOCK O 12 I/Os I/O168−I/O179 LOGIC BLOCK N 12 I/Os I/O156−I/O167 LOGIC BLOCK M 12 I/Os I/O144−I/O155 LOGIC BLOCK L 12 I/Os I/O132−I/O143 LOGIC BLOCK K 12 I/Os I/O120−I/O131 LOGIC BLOCK J 12 I/Os I/O108−I/O119 LOGIC BLOCK I 12 I/Os I/O96−I/O107 96 Page 11 of 64 Ultra37000 CPLD Family Logic Block Diagrams (continued) Clock/ Input Input CY37384/CY37384V 1 4 4 4 12 I/Os I/O0−I/O11 LOGIC BLOCK AA 12 I/Os LOGIC BLOCK AB I/O12−I/O23 12 I/Os I/O24−I/O35 LOGIC BLOCK AC LOGIC BLOCK AD 12 I/Os I/O36−I/O47 LOGIC BLOCK AE 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 16 PIM 36 16 LOGIC BLOCK AF 36 36 16 16 12 I/Os I/O48−I/O59 LOGIC BLOCK AG 36 36 16 16 12 I/Os I/O60−I/O71 LOGIC BLOCK AH 12 I/Os LOGIC BLOCK AI I/O72−I/O83 LOGIC BLOCK AJ 12 I/Os I/O84−I/O95 LOGIC BLOCK AK LOGIC BLOCK AL TDI TCK TMS 36 JTAG Tap Controller Document #: 38-03007 Rev. *E TDO 96 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 LOGIC BLOCK BL LOGIC BLOCK BK 12 I/Os I/O168−I/O191 LOGIC BLOCK BJ 12 I/Os I/O156−I/O179 LOGIC BLOCK BI 12 I/Os I/O144−I/O167 LOGIC BLOCK BH LOGIC BLOCK BG 12 I/Os I/O132−I/O155 LOGIC BLOCK BF LOGIC BLOCK BE 12 I/Os I/O120−I/O143 LOGIC BLOCK BD 12 I/Os I/O108−I/O131 LOGIC BLOCK BC 12 I/Os I/O96−I/O119 LOGIC BLOCK BB LOGIC BLOCK BA 12 I/Os I/O96−I/O107 96 Page 12 of 64 Ultra37000 CPLD Family Logic Block Diagrams (continued) CY37512/CY37512V Input Clock/ Input 4 1 4 4 12 I/Os I/O0−I/O11 LOGIC BLOCK AA 12 I/Os I/O12−I/O23 LOGIC BLOCK AB 12 I/Os I/O24−I/O35 LOGIC BLOCK AC LOGIC BLOCK AD 12 I/Os I/O36−I/O47 LOGIC BLOCK AE LOGIC BLOCK AF 12 I/Os I/O48−I/O59 12 I/Os I/O60−I/O71 LOGIC BLOCK AG 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 36 16 16 36 LOGIC BLOCK AH 36 16 16 LOGIC BLOCK AI 16 16 LOGIC BLOCK AJ 36 36 16 16 36 36 16 16 36 36 16 16 36 PIM 36 12 I/Os I/O72−I/O83 LOGIC BLOCK AK 12 I/Os I/O84−I/O95 LOGIC BLOCK AL 36 12 I/Os LOGIC BLOCK AM 36 16 16 36 36 I/O108−I/O119 LOGIC BLOCK AN 16 16 12 I/Os I/O120−I/O131 LOGIC BLOCK AO 36 36 16 16 LOGIC BLOCK AP 36 36 16 16 I/O96−I/O107 12 I/Os 132 TDI TCK TMS 36 JTAG Tap Controller LOGIC BLOCK BP LOGIC BLOCK BO 12 I/Os I/O252−I/O263 LOGIC BLOCK BN 12 I/Os I/O240−I/O251 LOGIC BLOCK BM 12 I/Os I/O228−I/O239 LOGIC BLOCK BL LOGIC BLOCK BK 12 I/Os I/O216−I/O227 LOGIC BLOCK BJ LOGIC BLOCK BI 12 I/Os I/O204−I/O215 LOGIC BLOCK BH LOGIC BLOCK BG 12 I/Os I/O192−I/O203 LOGIC BLOCK BF LOGIC BLOCK BE 12 I/Os I/O180−I/O191 LOGIC BLOCK BD 12 I/Os I/O168−I/O179 LOGIC BLOCK BC 12 I/Os I/O156−I/O167 LOGIC BLOCK BB 12 I/Os I/O144−I/O155 LOGIC BLOCK BA 12 I/Os I/O132−I/O143 132 TDO Document #: 38-03007 Rev. *E Page 13 of 64 Ultra37000 CPLD Family 5.0V Device Characteristics Maximum Ratings DC Voltage Applied to Outputs in High-Z State................................................–0.5V to +7.0V DC Input Voltage ............................................–0.5V to +7.0V (Above which the useful life may be impaired. For user guidelines, not tested.) DC Program Voltage............................................. 4.5 to 5.5V Current into Outputs .................................................... 16 mA Storage Temperature ................................. –65°C to +150°C Static Discharge Voltage........................................... > 2001V (per MIL-STD-883, Method 3015) Ambient Temperature with Power Applied............................................. –55°C to +125°C Latch-up Current..................................................... > 200 mA Supply Voltage to Ground Potential ............... –0.5V to +7.0V Operating Range[2] Ambient Temperature[2] Junction Temperature Output Condition VCC VCCO 0°C to +70°C 0°C to +90°C 5V 5V ± 0.25V 5V ± 0.25V 3.3V 5V ± 0.25V 3.3V ± 0.3V Industrial –40°C to +85°C –40°C to +105°C 5V 5V ± 0.5V 5V ± 0.5V 3.3V 5V ± 0.5V 3.3V ± 0.3V Military[3] –55°C to +125°C –55°C to +130°C 5V 5V ± 0.5V 5V ± 0.5V 3.3V 5V ± 0.5V 3.3V ± 0.3V Range Commercial 5.0V Device Electrical Characteristics Over the Operating Range Parameter VOH Description Output HIGH Voltage Test Conditions VCC = Min. Min. Typ. IOH = –2.0 mA VOHZ Output HIGH Voltage with Output Disabled[5] VCC = Max. (Mil)[4] V 4.5 V 3.6 V (Ind/Mil)[6] 3.6 V IOL = 16 mA (Com’l/Ind)[4] 0.5 V IOH = 0 µA VCC = Min. V 4.2 (Ind/Mil)[6] IOH = –150 µA Output LOW Voltage Unit V 2.4 IOH = 0 µA (Com’l)[6] IOH = –100 µA (Com’l)[6] VOL Max. IOH = –3.2 mA (Com’l/Ind)[4] 2.4 IOL = 12 mA (Mil)[4] 0.5 V Input HIGH Voltage Guaranteed Input Logical HIGH Voltage for all Inputs[7] 2.0 VCCmax V VIL Input LOW Voltage Guaranteed Input Logical LOW Voltage for all Inputs[7] –0.5 0.8 V IIX Input Load Current VI = GND OR VCC, Bus-Hold Disabled –10 10 µA IOZ Output Leakage Current VO = GND or VCC, Output Disabled, Bus-Hold Disabled –50 50 µA IOS Output Short Circuit Current[5, 8] VCC = Max., VOUT = 0.5V –30 –160 mA IBHL Input Bus-Hold LOW Sustaining Current VCC = Min., VIL = 0.8V +75 µA IBHH Input Bus-Hold HIGH Sustaining Current VCC = Min., VIH = 2.0V –75 µA IBHLO Input Bus-Hold LOW Overdrive Current VCC = Max. +500 µA IBHHO Input Bus-Hold HIGH Overdrive Current VCC = Max. –500 µA VIH Notes: 2. Normal Programming Conditions apply across Ambient Temperature Range for specified programming methods. For more information on programming the Ultra37000 Family devices, please refer to the Application Note titled “An Introduction to In System Reprogramming with the Ultra37000.” 3. TA is the “Instant On” case temperature. 4. IOH = –2 mA, IOL = 2 mA for TDO. 5. Tested initially and after any design or process changes that may affect these parameters. 6. When the I/O is output disabled, the bus-hold circuit can weakly pull the I/O to above 3.6V if no leakage current is allowed. Note that all I/Os are output disabled during ISR programming. Refer to the application note “Understanding Bus-Hold” for additional information. 7. These are absolute values with respect to device ground. All overshoots due to system or tester noise are included. 8. Not more than one output should be tested at a time. Duration of the short circuit should not exceed 1 second. VOUT = 0.5V has been chosen to avoid test problems caused by tester ground degradation. Document #: 38-03007 Rev. *E Page 14 of 64 Ultra37000 CPLD Family Inductance[5] 44-Lead 44-Lead 44-Lead 84-Lead 84-Lead 100-Lead 160-Lead 208-Lead TQFP PLCC CLCC PLCC CLCC TQFP TQFP PQFP Unit Parameter Description Test Conditions L Maximum Pin VIN = 5.0V Inductance at f = 1 MHz 2 5 2 8 5 8 9 11 nH Capacitance[5] Parameter Description Test Conditions Max. Unit CI/O Input/Output Capacitance VIN = 5.0V at f = 1 MHz at TA = 25°C 10 pF CCLK Clock Signal Capacitance VIN = 5.0V at f = 1 MHz at TA = 25°C 12 pF VIN = 5.0V at f = 1 MHz at TA = 25°C 16 pF CDP Dual-Function Pins Endurance Characteristics[5] Parameter N [9] Description Test Conditions Minimum Reprogramming Cycles Normal Programming 3.3V Device Characteristics Maximum Ratings Conditions[2] Min. Typ. Unit 1,000 10,000 Cycles DC Voltage Applied to Outputs in High-Z State................................................–0.5V to +7.0V (Above which the useful life may be impaired. For user guidelines, not tested.) Storage Temperature ................................. –65°C to +150°C Ambient Temperature with Power Applied............................................. –55°C to +125°C Supply Voltage to Ground Potential ............... –0.5V to +4.6V DC Input Voltage ............................................–0.5V to +7.0V DC Program Voltage............................................. 3.0 to 3.6V Current into Outputs ...................................................... 8 mA Static Discharge Voltage........................................... > 2001V (per MIL-STD-883, Method 3015) Latch-up Current..................................................... > 200 mA Operating Range[2] Range Ambient Temperature[2] Junction Temperature VCC[10] 0°C to +70°C 0°C to +90°C 3.3V ± 0.3V Commercial Industrial –40°C to +85°C –40°C to +105°C 3.3V ± 0.3V Military[3] –55°C to +125°C –55°C to +130°C 3.3V ± 0.3V 3.3V Device Electrical Characteristics Over the Operating Range Parameter VOH Description Output HIGH Voltage Test Conditions VCC = Min. IOH = –3 mA (Mil) VOL Output LOW Voltage VCC = Min. Min. IOH = –4 mA (Com’l)[4] Unit V [4] IOL = 8 mA (Com’l)[4] IOL = 6 mA Max. 2.4 0.5 V (Mil)[4] VIH Input HIGH Voltage Guaranteed Input Logical HIGH Voltage for all Inputs[7] 2.0 5.5 V VIL Input LOW Voltage Guaranteed Input Logical LOW Voltage for all Inputs[7] –0.5 0.8 V IIX Input Load Current VI = GND OR VCC, Bus-Hold Disabled –10 10 µA IOZ Output Leakage Current VO = GND or VCC, Output Disabled, Bus-Hold Disabled –50 50 µA IOS Output Short Circuit Current[5, 8] VCC = Max., VOUT = 0.5V –30 –160 mA IBHL Input Bus-Hold LOW Sustaining Current VCC = Min., VIL = 0.8V +75 IBHH Input Bus-Hold HIGH Sustaining Current VCC = Min., VIH = 2.0V –75 IBHLO Input Bus-Hold LOW Overdrive Current VCC = Max. µA µA +500 µA Input Bus-Hold HIGH Overdrive Current VCC = Max. –500 Notes: 9. Dual pins are I/O with JTAG pins. 10. For CY37064VP100-143AC, CY37064VP100-143BBC, CY37064VP44-143AC, CY37064VP48-143BAC; Operating Range: VCC is 3.3V± 0.16V. µA IBHHO Document #: 38-03007 Rev. *E Page 15 of 64 Ultra37000 CPLD Family Inductance[5] Parameter Description L Test Conditions 44Lead TQFP 44Lead PLCC 44Lead CLCC 84Lead PLCC 84Lead CLCC 100Lead TQFP 160Lead TQFP 2 5 2 8 5 8 9 Maximum Pin VIN = 3.3V Inductance at f = 1 MHz 208Lead PQFP Unit 11 nH Capacitance[5] Parameter Description Test Conditions Max. Unit CI/O Input/Output Capacitance VIN = 3.3V at f = 1 MHz at TA = 25°C 8 pF CCLK Clock Signal Capacitance VIN = 3.3V at f = 1 MHz at TA = 25°C 12 pF VIN = 3.3V at f = 1 MHz at TA = 25°C 16 pF CDP Dual Functional Pins [9] Endurance Characteristics[5] Parameter Description N Test Conditions Minimum Reprogramming Cycles Normal Programming Conditions [2] Min. Typ. Unit 1,000 10,000 Cycles AC Characteristics 5.0V AC Test Loads and Waveforms 238Ω (COM'L) 319Ω (MIL) 5V OUTPUT 170Ω (COM'L) 236Ω (MIL) 35 pF INCLUDING JIG AND SCOPE 238Ω (COM'L) 319Ω (MIL) 5V 3.0V OUTPUT 5 pF INCLUDING JIG AND SCOPE (b) (a) 170Ω (COM'L) GND 236Ω (MIL)