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XC4008E-4PC84I
Datasheet
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XILINX XC4062XL-2BG560I, XC4062XL-2BG560C, XC4062XL-2BG475I, XC4062XL-2BG475C, XC4062XL-2BG432I Datasheet

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May 14, 1999 (Version 1.6) 6-5
6
XC4000E and XC4000X Series Features
Note: Information in this data sheet covers the XC4000E,
XC4000EX, and XC4000XL families.Aseparatedatasheet covers the XC4000XLA and XC4000XV families. Electrical Specifications and package/pin information are covered in separate sections for each family to make the information easier to access,review,andprint.Foraccesstothesesec­tions, see the Xilinx WEBLINX web site at
• System featured Field-Programmable Gate Arrays
- Select-RAMTM memory: on-chip ultra-fast RAM with
- synchronous write option
- dual-port RAM option
- Fully PCI compliant (speed grades -2 and faster)
- Abundant flip-flops
- Flexible function generators
- Dedicated high-speed carry logic
- Wide edge decoders on each edge
- Hierarchy of interconnect lines
- Internal 3-state bus capability
- Eight global low-skew clock or signal distribution networks
• System Performance beyond 80 MHz
• Flexible Array Architecture
• Low Power Segmented Routing Architecture
• Systems-Oriented Features
- IEEE 1149.1-compatible boundary scan logic support
- Individually programmable output slew rate
- Programmable input pull-up or pull-down resistors
- 12 mA sink current per XC4000E output
• Configured by Loading Binary File
- Unlimited re-programmability
• Read Back Capability
- Program verification
- Internal node observability
• Backward Compatible with XC4000 Devices
• Development System runs on most common computer platforms
- Interfaces to popular design environments
- Fully automatic mapping, placement and routing
- Interactive design editor for design optimization
Low-Voltage Versions Available
• Low-Voltage Devices Function at 3.0 - 3.6 Volts
• XC4000XL: High Performance Low-Voltage Versions of XC4000EX devices
Additional XC4000X Series Features
• Highest Performance — 3.3 V XC4000XL
• Highest Capacity — Over 180,000 Usable Gates
• 5 V tolerant I/Os on XC4000XL
• 0.35 µm SRAM process for XC4000XL
• Additional Routing Over XC4000E
- almost twice the routing capacity for high-density
designs
• Buffered Interconnect for Maximum Speed Blocks
• Improved VersaRing
TM
I/O Interconnect forBetter Fixed
Pinout Flexibility
• 12 mA Sink Current Per XC4000X Output
• Flexible New High-Speed Clock Network
- Eight additional Early Buffers forshorter clockdelays
- Virtually unlimited number of clock signals
• Optional Multiplexer or 2-input Function Generator on Device Outputs
• Four Additional Address Bits in Master Parallel Configuration Mode
• XC4000XV Family offers the highest density with
0.25 µm 2.5 V technology
Introduction
XC4000 Series high-performance, high-capacity Field Pro­grammable Gate Arrays (FPGAs) provide the benefits of custom CMOS VLSI, while avoiding the initial cost, long development cycle, and inherent risk of a conventional masked gate array.
The result of thirteen years of FPGA design experience and feedbackfromthousandsof customers, these FPGAs com­bine architectural versatility, on-chip Select-RAM memory with edge-triggered and dual-port modes, increased speed, abundant routing resources, and new, sophisticated software to achieve fully automated implementation of complex, high-density, high-performance designs.
The XC4000E and XC4000X Series currently have 20 members, as shown in Table 1.
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XC4000E and XC4000X Series Field Programmable Gate Arrays
May 14, 1999 (Version 1.6)
00*
Product Specification
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XC4000E and XC4000X Series Field Programmable Gate Arrays
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* Max values of Typical Gate Range include 20-30% of CLBs used as RAM.
Note:
All functionality in low-voltage families is the same as in the corresponding 5-Volt family, except where numerical references are made to timing or power.
Description
XC4000 Series devices are implemented with a regular, flexible, programmable architecture of Configurable Logic Blocks (CLBs), interconnected by a powerful hierarchy of versatile routing resources, and surrounded by a perimeter of programmable Input/Output Blocks (IOBs). They have generous routing resources to accommodate the most complex interconnect patterns.
The devices are customized by loading configuration data into internal memory cells. The FPGA can either actively read its configuration data from an external serial or byte-parallel PROM (master modes), or the configuration data can be written into the FPGA from an external device (slave and peripheral modes).
XC4000 Series FPGAs are supported by powerful and sophisticated software, covering every aspect of design from schematic or behavioral entry, floor planning, simula­tion, automatic block placement and routing of intercon­nects, to the creation, downloading, and readback of the configuration bit stream.
Because Xilinx FPGAs can be reprogrammed an unlimited number of times, they can be used in innovative designs
where hardware is changed dynamically, or where hard­ware must be adapted to different user applications. FPGAs are ideal for shortening design and development cycles, and also offer a cost-effective solution for produc­tion rates well beyond 5,000 systems per month. For lowest high-volume unit cost, a design can first be implemented in the XC4000E or XC4000X, then migrated to one of Xilinx’ compatible HardWire mask-programmed devices.
Taking Advantage of Re-configuration
FPGA devices can be re-configured to change logic func­tion while resident in the system. This capability gives the system designer a new degree of freedom not available with any other type of logic.
Hardware can be changed as easily as software. Design updates or modifications are easy, and can be made to products already in the field. An FPGA caneven be re-con­figured dynamically to perform different functions at differ­ent times.
Re-configurable logic can be used to implement system self-diagnostics, create systems capable of being re-con­figured for different environments or operations, or imple­ment multi-purpose hardwarefora given application. As an added benefit, using re-configurable FPGA devices simpli­fies hardware design and debugging and shortens product time-to-market.
Table 1: XC4000E and XC4000X Series Field Programmable Gate Arrays
Device
Logic
Cells
Max Logic
Gates
(No RAM)
Max. RAM
Bits
(No Logic)
Typical
Gate Range
(Logic and RAM)*
CLB
Matrix
Total
CLBs
Number
of
Flip-Flops
Max.
User I/O
XC4002XL 152 1,600 2,048 1,000 - 3,000 8 x 8 64 256 64 XC4003E 238 3,000 3,200 2,000 - 5,000 10 x 10 100 360 80 XC4005E/XL 466 5,000 6,272 3,000 - 9,000 14 x 14 196 616 112 XC4006E 608 6,000 8,192 4,000 - 12,000 16 x 16 256 768 128 XC4008E 770 8,000 10,368 6,000 - 15,000 18 x 18 324 936 144 XC4010E/XL 950 10,000 12,800 7,000 - 20,000 20 x 20 400 1,120 160 XC4013E/XL 1368 13,000 18,432 10,000 - 30,000 24 x 24 576 1,536 192 XC4020E/XL 1862 20,000 25,088 13,000 - 40,000 28 x 28 784 2,016 224 XC4025E 2432 25,000 32,768 15,000 - 45,000 32 x 32 1,024 2,560 256 XC4028EX/XL 2432 28,000 32,768 18,000 - 50,000 32 x 32 1,024 2,560 256 XC4036EX/XL 3078 36,000 41,472 22,000 - 65,000 36 x 36 1,296 3,168 288 XC4044XL 3800 44,000 51,200 27,000 - 80,000 40 x 40 1,600 3,840 320 XC4052XL 4598 52,000 61,952 33,000 - 100,000 44 x 44 1,936 4,576 352 XC4062XL 5472 62,000 73,728 40,000 - 130,000 48 x 48 2,304 5,376 384 XC4085XL 7448 85,000 100,352 55,000 - 180,000 56 x 56 3,136 7,168 448
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XC4000E and XC4000X Series Field Programmable Gate Arrays
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XC4000E and XC4000X Series Compared to the XC4000
For readers already familiar with the XC4000 family of Xil­inx Field Programmable Gate Arrays, the major new fea­tures in the XC4000 Series devices are listed in this section. The biggest advantages of XC4000E and XC4000X devices are significantly increased system speed, greater capacity, and new architectural features, particularly Select-RAM memory. The XC4000X devices also offer many new routing features, including special high-speed clock buffers that can be used to capture input data with minimal delay.
Any XC4000E device is pinout- and bitstream-compatible with the corresponding XC4000 device. An existing XC4000 bitstream can be used to program an XC4000E device. However, since the XC4000E includes many new features, an XC4000E bitstream cannot be loaded into an XC4000 device.
XC4000X Series devices are not bitstream-compatible with equivalent array size devices in the XC4000 or XC4000E families. However, equivalent array size devices, such as the XC4025, XC4025E, XC4028EX, and XC4028XL, are pinout-compatible.
Improvements in XC4000E and XC4000X
Increased System Speed
XC4000E and XC4000X devices can run at synchronous system clock rates of up to 80 MHz, and internal perfor­mance can exceed 150 MHz.This increase in performance overthepreviousfamilies stems from improvements in both device processing and system architecture. XC4000 Series devices use a sub-micron multi-layer metal process. In addition, many architectural improvements have been made, as described below.
The XC4000XL family is a high performance 3.3V family based on 0.35µ SRAM technology and supports system speeds to 80 MHz.
PCI Compliance
XC4000 Series -2 and faster speed grades are fully PCI compliant. XC4000E and XC4000Xdevicescan be used to implement a one-chip PCI solution.
Carry Logic
The speed of the carry logic chain has increased dramati­cally. Some parameters, such as the delay on the carry chain through a single CLB (TBYP), have improved by as
much as 50% from XC4000 values. See “Fast Carry Logic”
on page 18 for more information.
Select-RAM Memory: Edge-Triggered, Synchro­nous RAM Modes
The RAM in any CLB can be configured for synchronous, edge-triggered, write operation. The read operation is not affected by this change to an edge-triggered write.
Dual-Port RAM
A separate option converts the 16x2 RAM in any CLB into a 16x1 dual-port RAM with simultaneous Read/Write.
The function generators in each CLB can be configured as either level-sensitive (asynchronous) single-port RAM, edge-triggered (synchronous) single-port RAM, edge-trig­gered (synchronous) dual-port RAM, or as combinatorial logic.
Configurable RAM Content
The RAM content can now be loaded at configuration time, so that the RAM starts up with user-defined data.
H Function Generator
In current XC4000 Series devices,the H function generator is more versatile than in the original XC4000. Its inputs can come not only from the F and G function generators but also from up to three of the four control input lines. The H function generator can thus be totally or partially indepen­dent of the other two function generators, increasing the maximum capacity of the device.
IOB Clock Enable
The two flip-flops in each IOB havea common clock enable input, which through configuration can be activated individ­ually for the input or output flip-flop or both. This clock enable operates exactly like the EC pin on the XC4000 CLB. This new feature makes the IOBs more versatile, and avoids the need for clock gating.
Output Drivers
The output pull-up structure defaults to a TTL-like totem-pole. This driver is an n-channel pull-up transistor, pulling to a voltage one transistor threshold below Vcc, just like the XC4000 family outputs. Alternatively, XC4000 Series devices can be globally configured with CMOS out­puts, with p-channel pull-up transistors pulling to Vcc. Also, the configurable pull-up resistor in the XC4000 Series is a p-channel transistor that pulls to Vcc, whereas in the origi­nal XC4000 family it is an n-channel transistor that pulls to a voltage one transistor threshold below Vcc.
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Input Thresholds
The input thresholds of 5V devices can be globally config­ured for either TTL (1.2 V threshold) or CMOS (2.5 V threshold), just like XC2000 and XC3000 inputs. The two global adjustments of input threshold and output level are independent of each other. The XC4000XL family has an input threshold of 1.6V, compatible with both 3.3V CMOS and TTL levels.
Global Signal Access to Logic
There is additional access from global clocks to the F and G function generator inputs.
Configuration Pin Pull-Up Resistors
During configuration, these pins have weak pull-up resis­tors. For the most popular configuration mode, Slave Serial, the mode pins can thus be left unconnected. The three mode inputs can be individually configured with or without weak pull-up or pull-down resistors. A pull-down resistor value of 4.7 k is recommended.
The three mode inputs can be individually configured with or without weak pull-up or pull-down resistors after configu­ration.
The PROGRAM input pin has a permanent weak pull-up.
Soft Start-up
Like the XC3000A, XC4000 Series devices have “Soft Start-up.” When the configuration process is finished and the device starts up, the first activation of the outputs is automatically slew-rate limited. This feature avoids poten­tial ground bounce when all outputs are turned on simulta­neously. Immediately after start-up, the slew rate of the individual outputs is, as in the XC4000 family, determined by the individual configuration option.
XC4000 and XC4000A Compatibility
Existing XC4000 bitstreams can be used to configure an XC4000E device.XC4000A bitstreams must be recompiled for use with the XC4000E due to improved routing resources, although the devices are pin-for-pincompatible.
Additional Improvements in XC4000X Only
Increased Routing
New interconnect in the XC4000X includes twenty-two additional vertical lines in each column of CLBs and twelve newhorizontallines in each rowofCLBs.Thetwelve“Quad Lines” in each CLB row and column include optional repow­ering buffers for maximum speed. Additional high-perfor­mance routing near the IOBs enhances pin flexibility.
Faster Input and Output
A fast,dedicatedearly clocksourcedbyglobalclockbuffers is availablefor the IOBs. To ensure synchronization with the regular global clocks, a Fast Capture latch driven by the early clock is available. The input data can be initially loaded into the Fast Capture latch withthe early clock, then transferred to the input flip-flop or latch with the low-skew global clock. A programmable delay on the input can be used to avoid hold-time requirements. See “IOB Input Sig-
nals” on page 20 for more information.
Latch Capability in CLBs
Storage elements in the XC4000X CLB can be configured as either flip-flops or latches. This capability makes the FPGA highly synthesis-compatible.
IOB Output MUX From Output Clock
A multiplexer in the IOB allows the output clock to select either the output data or the IOB clockenableas the output to the pad. Thus,twodifferentdata signals can share a sin­gle output pad, effectively doubling the number of device outputs without requiring a larger, more expensive pack­age. This multiplexer can also be configured as an AND-gate to implement a very fast pin-to-pin path. See
“IOB Output Signals” on page 23 for more information.
Additional Address Bits
Larger devices require more bits of configuration data. A daisy chain of several large XC4000X devices may require a PROM that cannot be addressed by the eighteen address bits supported in the XC4000E. The XC4000X Series therefore extends the addressing in Master Parallel config­uration mode to 22 bits.
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Detailed Functional Description
XC4000 Series devices achieve high speed through advanced semiconductor technology and improved archi­tecture. The XC4000E and XC4000X support system clock rates of up to 80 MHz and internal performance in excess of 150 MHz. Compared to older Xilinx FPGA families, XC4000 Series devices are more powerful. They offer on-chip edge-triggered and dual-port RAM, clock enables on I/O flip-flops, and wide-input decoders. They are more versatile in many applications, especially those involving RAM. Design cycles are faster due to a combination of increased routing resources and more sophisticated soft­ware.
Basic Building Blocks
Xilinx user-programmable gate arrays include two major configurable elements: configurable logic blocks (CLBs) and input/output blocks (IOBs).
• CLBs provide the functional elements for constructing
the user’s logic.
• IOBs provide the interface between the package pins
and internal signal lines.
Three other types of circuits are also available:
• 3-State buffers (TBUFs) driving horizontal longlines are
associated with each CLB.
• Wide edge decoders are availablearoundthe periphery
of each device.
• An on-chip oscillator is provided. Programmable interconnect resources provide routing
paths to connect the inputs and outputs of these config­urable elements to the appropriate networks.
The functionality of each circuit block is customized during configuration by programming internal static memory cells. The values stored in these memory cells determine the logic functions and interconnections implemented in the FPGA. Each of these available circuits is described in this section.
Configurable Logic Blocks (CLBs)
Configurable Logic Blocks implement most of the logic in an FPGA. The principal CLB elements are shown in
Figure 1. Two 4-input function generators (F and G) offer
unrestricted versatility. Most combinatorial logic functions need four or fewer inputs. However, a third function gener­ator (H) is provided. The H function generator has three inputs. Either zero, one, or two of these inputs can be the outputs of F and G; the other input(s) are from outside the CLB. The CLB can, therefore, implement certain functions of up to nine variables, like parity check or expand­able-identity comparison of two sets of four inputs.
Each CLB contains two storage elements that can be used to store the function generator outputs. However, the stor­age elements and function generators can also be used independently. These storage elements can be configured as flip-flops in both XC4000E and XC4000X devices; in the XC4000X they can optionally be configured as latches. DIN can be used as a direct input to either of the two storage elements. H1 can drive the other through the H function generator. Function generator outputs can also drive two outputs independent of the storage element outputs. This versatility increases logic capacity and simplifies routing.
Thirteen CLB inputs and four CLB outputs provide access to the function generators and storage elements. These inputs and outputs connect to the programmable intercon­nect resources outside the block.
Function Generators
Four independent inputs are provided to each of two func­tion generators (F1 - F4 and G1 - G4). These function gen­erators, with outputs labeled F’ and G’, are each capableof implementing any arbitrarily defined Boolean function of four inputs. The function generators are implemented as memory look-up tables. The propagation delay is therefore independent of the function implemented.
A third function generator, labeled H’, can implement any Boolean function of its three inputs. Two of these inputs can optionally be the F’ and G’ functional generator outputs. Alternatively, one or both of these inputs can come from outside the CLB (H2, H0). The third input must come from outside the block (H1).
Signals from the function generators can exit the CLB on two outputs.F’orH’canbeconnectedtotheXoutput.G’or H’ can be connected to the Y output.
A CLB can be used to implement any of the following func­tions:
• any function of up to four variables, plus any second function of up to four unrelated variables, plus any third
function of up to three unrelated variables
1
• any single function of five variables
• any function of four variables together with some functions of six variables
• some functions of up to nine variables.
Implementing wide functions in a single block reduces both the number of blocks required and the delay in the signal path, achieving both increased capacity and speed.
The versatility of the CLB function generators significantly improves system speed. In addition, the design-software tools can deal with each function generator independently. This flexibility improves cell usage.
1. When three separate functions are generated, one of the function outputs must be captured in a flip-flop internal to the CLB. Only two unregistered function generator outputs are available from the CLB.
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Flip-Flops
The CLB can pass the combinatorial output(s) to the inter­connect network, but can also store the combinatorial results or other incoming data in one or two flip-flops, and connect their outputs to the interconnect network as well.
The two edge-triggered D-type flip-flops have common clock (K) and clock enable (EC) inputs. Either or both clock inputs can also be permanently enabled. Storage element functionality is described in Table 2.
Latches (XC4000X only)
The CLB storage elements can also be configured as latches. The two latches have common clock (K) and clock enable (EC) inputs. Storage element functionality is described in Table 2.
Clock Input
Each flip-flop can be triggered on either the rising or falling clock edge. The clock pin is shared by both storage ele­ments. However, the clock is individually invertible for each storage element. Any inverter placed on the clock input is automatically absorbed into the CLB.
Clock Enable
The clock enable signal (EC) is active High. The EC pin is shared by both storage elements. If left unconnected for either, the clock enable for that storage element defaults to the active state. EC is not invertible within the CLB.
LOGIC
FUNCTION
OF
G1-G4
G
4
G
3
G
2
G
1
G'
LOGIC
FUNCTION
OF
F1-F4
F
4
F
3
F
2
F
1
F'
LOGIC
FUNCTION
OF
F', G',
AND
H1
H'
DIN F' G' H'
DIN F' G' H'
G' H'
H' F'
S/R
CONTROL
D
EC
RD
Bypass
Bypass
SD
YQ
XQ
Q
S/R
CONTROL
D
EC
RD
SD
Q
1
1
K (CLOCK)
Multiplexer Controlled by Configuration Program
Y
X
DIN/H
2
H
1
SR/H
0
EC
X6692
C1 • • • C4
4
Figure 1: Simplified Block Diagram of XC4000 Series CLB (RAM and Carry Logic functions not shown)
Table 2: CLB Storage Element Functionality (active rising edge is shown)
Mode K EC SR D Q
Power-Up or
GSR
XXXXSR
Flip-Flop
XX1XSR
__/ 1* 0* D D
0X0*XQ
Latch
11*0*XQ 01*0*DD
Both X 0 0* X Q
Legend:
X __/ SR
0* 1*
Don’t care Rising edge Set or Reset value. Reset is default. Input is Low or unconnected (default value) Input is High or unconnected (default value)
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Set/Reset
An asynchronous storage element input (SR) can be con­figured as either set or reset. This configuration option determines the state in which each flip-flop becomes oper­ational after configuration. It also determines the effectof a Global Set/Reset pulse during normal operation, and the effect of a pulse on the SR pin of the CLB. All three set/reset functions for any single flip-flop are controlled by the same configuration data bit.
The set/reset state can be independently specified for each flip-flop. This input can also be independently disabled for either flip-flop.
The set/reset state is specified by using the INIT attribute, or by placing the appropriate set or reset flip-flop library symbol.
SR is active High. It is not invertible within the CLB.
Global Set/Reset
A separate Global Set/Reset line (not shown in Figure 1) sets or clears each storage element during power-up, re-configuration, or when a dedicated Reset net is driven active. This global net (GSR) does not compete with other routing resources; it uses a dedicated distribution network.
Each flip-flop is configured as either globally set or reset in the same way that the local set/reset (SR) is specified. Therefore, if a flip-flop is set by SR, it is also set by GSR. Similarly, a reset flip-flop is reset by both SR and GSR.
GSR can be driven from any user-programmable pin as a global reset input. To use this globalnet, place an input pad and input buffer in the schematic or HDL code, driving the GSR pin of the STARTUP symbol. (See Figure 2.) A spe­cific pin location can be assigned to this input using a LOC attribute or property, just as with any other user-program­mable pad. An inverter can optionally be inserted after the input buffer to invert the sense of the Global Set/Reset sig­nal.
Alternatively, GSR can be driven from any internal node.
Data Inputs and Outputs
The source of a storage element data input is programma­ble. It is driven by any of the functions F’, G’, and H’, or by the Direct In (DIN) blockinput.Theflip-flopsorlatchesdrive the XQ and YQ CLB outputs.
Two fast feed-through paths are available, as shown in
Figure 1. A two-to-one multiplexer on each of the XQ and
YQ outputs selects between a storage element output and any of the control inputs. This bypass is sometimes used by the automated router to repower internal signals.
Control Signals
MultiplexersintheCLBmapthefourcontrolinputs(C1- C4 in Figure 1) into the four internal control signals (H1, DIN/H2, SR/H0, and EC). Any of theseinputscan drive any of the four internal control signals.
When the logic function is enabled, the four inputs are:
• EC — Enable Clock
• SR/H0 — Asynchronous Set/Reset or H function generator Input 0
• DIN/H2 — Direct In or H function generator Input 2
• H1 — H function generator Input 1.
When the memory function is enabled, the four inputs are:
• EC — Enable Clock
• WE — Write Enable
• D0 — Data Input to F and/or G function generator
• D1 — Data input to G function generator (16x1 and 16x2 modes) or 5th Address bit (32x1 mode).
Using FPGA Flip-Flops and Latches
The abundance of flip-flops in the XC4000 Series invites pipelined designs. This is a powerful way of increasing per­formance by breaking the function into smaller subfunc­tions and executing them in parallel, passing on the results through pipeline flip-flops. This method should be seriously considered wherever throughput is more important than latency.
To include a CLB flip-flop, place the appropriate library symbol. For example, FDCE is a D-type flip-flop with clock enable and asynchronous clear. The corresponding latch symbol (for the XC4000X only) is called LDCE.
In XC4000 Series devices,theflipflopscanbeusedasreg­isters or shift registers without blocking the function gener­ators from performing a different, perhaps unrelated task. This abilityincreasesthefunctionalcapacityofthedevices.
The CLB setup time is specified between the function gen­erator inputs and the clockinput K. Therefore, the specified CLB flip-flop setup time includes the delay through the function generator.
Using Function Generators as RAM
Optional modes for each CLB make the memory look-up tables in the F’ and G’ function generators usable as an array of Read/Write memory cells. Available modes are level-sensitive (similar to the XC4000/A/H families), edge-triggered, and dual-port edge-triggered. Depending on the selected mode, a single CLB can be configured as either a 16x2, 32x1, or 16x1 bit array.
PAD
IBUF
GSR GTS
CLK
DONEIN
Q1Q4
Q2 Q3
STARTUP
X5260
Figure 2: Schematic Symbols for Global Set/Reset
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Supported CLB memory configurations and timing modes for single- and dual-port modes are shown in Table 3.
XC4000 Series devices are the first programmable logic devices with edge-triggered (synchronous) and dual-port RAM accessible to the user. Edge-triggered RAM simpli­fies system timing. Dual-port RAM doubles the effective throughput of FIFO applications. These features can be individually programmed in any XC4000 Series CLB.
Advantages of On-Chip and Edge-Triggered RAM
The on-chip RAM is extremely fast.Thereadaccess time is the same as the logic delay. The write access time is slightly slower. Both access times are much faster than any off-chip solution, because they avoid I/O delays.
Edge-triggered RAM, also called synchronous RAM, is a feature never before available in a Field Programmable Gate Array. The simplicity of designing with edge-triggered RAM, and the markedly higher achievable performance, add up to a significant improvement over existing devices with on-chip RAM.
Three application notes are available from Xilinx that dis­cuss edge-triggered RAM: “
XC4000E Edge-Triggered and
Dual-Port RAM Capability,
”“
Implementing FIFOs in
XC4000E RAM,
” and “
Synchronous and Asynchronous
FIFO Designs
.” All three application notes apply to both
XC4000E and XC4000X RAM.
RAM Configuration Options
The function generators in any CLB can be configured as RAM arrays in the following sizes:
• Two 16x1 RAMs: two data inputs and two data outputs with identical or, if preferred, different addressing for each RAM
• One 32x1 RAM: one data input and one data output.
One F or Gfunction generator can be configuredas a 16x1 RAM while the other function generators are used to imple­ment any function of up to 5 inputs.
Additionally, the XC4000 Series RAM may have either of two timing modes:
• Edge-Triggered (Synchronous): data written by the designated edge of the CLB clock. WE acts as a true clock enable.
• Level-Sensitive (Asynchronous): an external WE signal acts as the write strobe.
The selected timing mode applies to both function genera­tors within a CLB when both are configured as RAM.
The number of read ports is also programmable:
• Single Port: each function generator has a common read and write port
• Dual Port: both function generators are configured together as a single 16x1 dual-port RAM with one write port and two read ports. Simultaneous read and write operations to the same or different addresses are supported.
RAM configuration options are selected by placing the appropriate library symbol.
Choosing a RAM Configuration Mode
The appropriate choice of RAM mode for a given design should be based on timing and resource requirements, desired functionality, and the simplicity of the design pro­cess. Recommended usage is shown in Table 4.
The difference between level-sensitive, edge-triggered, and dual-port RAM is only in the write operation. Read operation and timing is identical for all modes of operation.
RAM Inputs and Outputs
The F1-F4 and G1-G4 inputs to the function generators act as address lines, selecting a particular memory cell in each look-up table.
The functionality of the CLB control signals changes when the function generators are configured as RAM. The DIN/H2, H1, and SR/H0 lines become the two data inputs (D0, D1) and the Write Enable (WE) input for the 16x2 memory. When the 32x1 configuration is selected, D1 acts as the fifth address bit and D0 is the data input.
The contents of the memory cell(s) being addressed are available at the F’ and G’ function-generator outputs. They can exittheCLBthroughitsXandYoutputs,orcan be cap­tured in the CLB flip-flop(s).
Configuring the CLB function generators as Read/Write memory does not affect the functionality of the other por-
Table 3: Supported RAM Modes
16
x 1
16
x 2
32
x 1
Edge-
Triggered
Timing
Level-
Sensitive
Timing
Single-Port √√√ Dual-Port
Table 4: RAM Mode Selection
Level-Sens
itive
Edge-Trigg
ered
Dual-Port
Edge-Trigg
ered
Use for New Designs?
No Yes Yes
Size (16x1, Registered)
1/2 CLB 1/2 CLB 1 CLB
Simultaneous Read/Write
No No Yes
Relative Performance
X2X
2X (4X
effective)
R
May 14, 1999 (Version 1.6) 6-13
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
tions of the CLB, with the exception of the redefinition of the control signals. In 16x2 and 16x1 modes, the H’ function generator can be used to implement Boolean functions of F’, G’, and D1, and the D flip-flops can latch theF’,G’,H’,or D0 signals.
Single-Port Edge-Triggered Mode
Edge-triggered (synchronous) RAM simplifies timing requirements. XC4000 Series edge-triggered RAM timing operates like writing to a data register. Data and address are presented. The register is enabled for writing by a logic High on the write enable input, WE. Then a rising or falling clock edge loads the data into the register, as shown in
Figure 3.
Complex timing relationships between address, data, and write enable signals are not required, and theexternalwrite enable pulse becomes a simple clock enable. The active edge of WCLK latches the address, input data, and WE sig-
nals. An internal write pulse is generated that performs the write. See Figure 4 and Figure 5 for block diagrams of a CLB configured as 16x2 and 32x1 edge-triggered, sin­gle-port RAM.
The relationships between CLB pins and RAM inputs and outputs for single-port, edge-triggered mode are shown in
Table 5.
The Write Clock input (WCLK) can be configured as active on either the rising edge (default) or the falling edge. It uses the same CLB pin (K) used to clock the CLB flip-flops,butit can be independently inverted. Consequently, the RAM output can optionally be registered within the same CLB either by the same clock edge as the RAM, or by the oppo­site edge of this clock. The sense of WCLK applies to both function generators in the CLB when both are configured as RAM.
The WE pin is active-High and is not invertible within the CLB.
Note: The pulse following the active edge of WCLK (T
WPS
in Figure 3) must be less than one millisecond wide. For most applications, this requirement is not overly restrictive; however, it must not be forgotten. Stopping WCLK at this point in the write cyclecould result in excessivecurrent and even damage to the larger devices if many CLBs are con­figured as edge-triggered RAM.
X6461
WCLK (K)
WE
ADDRESS
DATA IN
DATA OUT OLD NEW
T
DSS
T
DHS
T
ASS
T
AHS
T
WSS
T
WPS
T
WHS
T
WOS
T
ILO
T
ILO
Figure 3: Edge-Triggered RAM Write Timing
Table 5: Single-Port Edge-Triggered RAM Signals
RAM Signal CLB Pin Function
D D0 or D1 (16x2,
16x1), D0 (32x1)
Data In
A[3:0] F1-F4 or G1-G4 Address A[4] D1 (32x1) Address WE WE Write Enable WCLK K Clock SPO
(Data Out)
F’ or G’ Single Port Out
(Data Out)
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XC4000E and XC4000X Series Field Programmable Gate Arrays
6-14 May 14, 1999 (Version 1.6)
G'
4
G1 • • • G4
F1 • • • F4
C1 • • • C4
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
X6752
4
4
MUX
F'
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
READ
ADDRESS
READ
ADDRESS
WRITE PULSE
LATCH ENABLE
LATCH ENABLE
K
(CLOCK)
WE
D
1
D
0
EC
WRITE PULSE
MUX
4
4
Figure 4: 16x2 (or 16x1) Edge-Triggered Single-Port RAM
G'
4
G1 • • • G4
F1 • • • F4
C1 • • • C4
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
X6754
4
4
MUX
F'
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
READ
ADDRESS
READ
ADDRESS
WRITE PULSE
LATCH ENABLE
LATCH ENABLE
K
(CLOCK)
WE
D1/A
4
D
0
EC
EC
WRITE PULSE
MUX
4
4
H'
Figure 5: 32x1 Edge-Triggered Single-Port RAM (F and G addresses are identical)
R
May 14, 1999 (Version 1.6) 6-15
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
Dual-Port Edge-Triggered Mode
In dual-port mode, both the F and G function generators are used to create a single 16x1 RAM array with one write port and two read ports. The resulting RAM array can be read and written simultaneously at two independent addresses. Simultaneous read and write operations at the same address are also supported.
Dual-port mode always has edge-triggered write timing, as shown in Figure 3.
Figure 6 shows a simple model of an XC4000 Series CLB
configured as dual-port RAM. One address port, labeled A[3:0], supplies both the read and write address for the F function generator. This function generator behaves the same as a 16x1 single-port edge-triggered RAM array. The RAM output, Single Port Out (SPO), appears at the F func­tion generator output. SPO, therefore, reflects the data at address A[3:0].
The other address port, labeled DPRA[3:0] for Dual Port Read Address, supplies the read address for the G function generator. The write address for the G function generator, however, comes from the address A[3:0]. The output from this 16x1 RAM array, Dual Port Out (DPO), appears at the G function generator output. DPO, therefore, reflects the data at address DPRA[3:0].
Therefore, by using A[3:0] for the write address and DPRA[3:0] for the read address, and reading only the DPO output, a FIFO that can read and write simultaneously is easily generated. Simultaneous access doubles the effec­tive throughput of the FIFO.
The relationships between CLB pins and RAM inputs and outputs for dual-port, edge-triggered mode are shown in
Table 6. See Figure 7 on page 16 for a block diagram of a
CLB configured in this mode.
Table 6: Dual-Port Edge-Triggered RAM Signals
Note: The pulse following the active edge of WCLK (T
WPS
in Figure 3) must be less than one millisecond wide. For most applications, this requirement is not overly restrictive; however, it must not be forgotten. Stopping WCLK at this point in the write cyclecould result in excessivecurrent and even damage to the larger devices if many CLBs are con­figured as edge-triggered RAM.
Single-Port Level-Sensitive Timing Mode Note: Edge-triggered mode is recommended for all new
designs. Level-sensitive mode, also called asynchronous mode, is still supported for XC4000 Series backward-com­patibility with the XC4000 family.
Level-sensitive RAM timing is simple in concept but can be complicated in execution. Data and address signals are presented, then a positive pulse on the write enable pin (WE) performs a write into the RAM at the designated address. As indicated by the “level-sensitive” label, this RAM acts likea latch. During the WE High pulse, changing the data lines results in newdatawritten to the old address. Changing the address lines while WE is High results in spu­rious data written to the new address—and possibly at other addresses as well, as the address lines inevitably do not all change simultaneously.
The user must generate a carefully timed WE signal. The delayonthe WE signal and the address lines must be care­fully verified to ensure that WE does not become active until after the address lines have settled, and that WE goes inactive before the address lines change again. The data must be stable before and after the falling edge of WE.
In practical terms, WE isusually generated by a 2X clock. If a 2X clock is not available, the falling edge of the system clock can be used. However, there are inherent risks in this approach, since the WE pulse must be guaranteed inactive before the next rising edge of the system clock. Several older application notes are available from Xilinx that dis­cuss the design of level-sensitive RAMs. These application notes include XAPP031, “
Using the XC4000 RAM Capabil-
ity
,” and XAPP042, “
High-Speed RAM Design in XC4000
.” However, the edge-triggered RAM available in the XC4000 Series is superior to level-sensitive RAM for almost every application.
WE
WE DDQ
DQ
D
DPRA[3:0]
A[3:0]
AR[3:0] AW[3:0]
WE D AR[3:0] AW[3:0]
RAM16X1D Primitive
F Function Generator
G Function Generator
DPO (Dual Port Out)
Registered DPO
SPO (Single Port Out)
Registered SPO
WCLK
X6755
Figure 6: XC4000 Series Dual-Port RAM, Simple Model
RAM Signal CLB Pin Function
D D0 Data In A[3:0] F1-F4 Read Address for F,
Write Address for F and G DPRA[3:0] G1-G4 Read Address for G WE WE Write Enable WCLK K Clock SPO F’ Single Port Out
(addressed by A[3:0]) DPO G’ Dual Port Out
(addressed by DPRA[3:0])
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XC4000E and XC4000X Series Field Programmable Gate Arrays
6-16 May 14, 1999 (Version 1.6)
Figure 8 shows the write timing for level-sensitive, sin-
gle-port RAM. The relationships between CLB pins and RAM inputs and
outputs for single-port level-sensitive mode are shown in
Table 7. Figure 9 and Figure 10 show blockdiagrams of a CLB con-
figured as 16x2 and 32x1 level-sensitive, single-port RAM.
Initializing RAM at Configuration
Both RAM and ROM implementations of the XC4000 Series devices are initialized during configuration. The ini­tial contents are defined via an INIT attribute or property
attached to the RAM or ROM symbol, as described in the schematic library guide. If not defined, all RAM contents are initialized to all zeros, by default.
RAM initialization occurs only during configuration. The RAM content is not affected by Global Set/Reset.
Table 7: Single-Port Level-Sensitive RAM Signals
G'
G1 • • • G4
F1 • • • F4
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
X6748
4
4
MUX
F'
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
READ
ADDRESS
READ
ADDRESS
WRITE PULSE
LATCH ENABLE
LATCH ENABLE
K
(CLOCK)
WRITE PULSE
MUX
4
4
C1 • • • C4
4
WE
D
1
D
0
EC
Figure 7: 16x1 Edge-Triggered Dual-Port RAM
RAM Signal CLB Pin Function
D D0 or D1 Data In A[3:0] F1-F4 or G1-G4 Address WE WE Write Enable O F’ or G’ Data Out
WC
T
ADDRESS
WRITE ENABLE
DATA IN
AS
T
WP
T
DS
T
DH
T
REQUIRED
AH
T
X6462
Figure 8: Level-Sensitive RAM Write Timing
R
May 14, 1999 (Version 1.6) 6-17
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
Enable
G'
4
G1 • • • G4
F1 • • • F4
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
X6746
4
READ ADDRESS
MUX
Enable
F'
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
4
READ ADDRESS
MUX
4
C1 • • • C4
4
WE
D
1
D
0
EC
Figure 9: 16x2 (or 16x1) Level-Sensitive Single-Port RAM
Enable
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
X6749
4
READ ADDRESS
MUX
Enable
WRITE
DECODER
1 of 16
D
IN
16-LATCH
ARRAY
4
READ ADDRESS
MUX
G'
4
G1 • • • G4
F1 • • • F4
C1 • • • C4
4
F'
WE
D1/A
4
D
0
EC
4
H'
Figure 10: 32x1 Level-Sensitive Single-Port RAM (F and G addresses are identical)
R
XC4000E and XC4000X Series Field Programmable Gate Arrays
6-18 May 14, 1999 (Version 1.6)
Fast Carry Logic
Each CLB F and G function generator contains dedicated arithmetic logic for the fast generation of carry and borrow signals. This extra output is passed on to the function gen­erator in the adjacent CLB. The carry chain is independent of normal routing resources.
Dedicated fast carry logic greatly increases the efficiency and performance of adders, subtractors, accumulators, comparators and counters. It also opens the door to many new applications involving arithmetic operation, where the previousgenerationsofFPGAs were not fastenough or too inefficient. High-speed address offset calculations in micro­processor or graphics systems, and high-speed addition in digital signal processing are two typical applications.
The two 4-input function generators can be configured as a 2-bit adder with built-in hidden carry that can be expanded to any length. This dedicated carry circuitry is so fast and efficient that conventional speed-up methods like carry generate/propagate are meaningless even at the 16-bit level, and of marginal benefit at the 32-bit level.
This fast carry logic is one of the more significant features of the XC4000 Series, speedingup arithmetic and counting into the 70 MHz range.
The carry chain in XC4000E devices can run either up or down. At the top and bottom of the columns where there are no CLBs aboveor below, the carry is propagated to the right. (See Figure 11.) In order to improve speed in the high-capacity XC4000X devices, which can potentially have very long carry chains, the carry chain travels upward only, as shown in Figure 12. Additionally,standardintercon­nect can be used to route a carry signal in the downward direction.
Figure 13 on page 19 shows an XC4000E CLB with dedi-
cated fast carry logic. The carry logic in the XC4000X is similar, except that COUT exits at the top only, and the sig­nal CINDOWN does not exist. As shown in Figure 13, the carry logic shares operandandcontrol inputs with the func­tion generators. The carry outputs connect to the function generators, where they are combined with the operands to form the sums.
Figure 14 on page 20 shows the details of the carry logic
for the XC4000E. This diagram shows the contents of the box labeled “CARRY LOGIC” in Figure 13. The XC4000X carry logic is very similar, but a multiplexer on the pass-through carry chain has been eliminated to reduce delay. Additionally, in the XC4000X the multiplexer on the G4 path has a memory-programmable 0 input, which per­mits G4 to directly connect to COUT. G4 thus becomes an additional high-speed initialization path for carry-in.
The dedicated carry logic is discussed in detail in Xilinx document XAPP 013: “
Using the Dedicated Carry Logic in
XC4000
.” This discussion also applies to XC4000E devices, and to XC4000X devices when the minor logic changes are taken into account.
The fast carry logic can be accessed by placing special library symbols, or by using Xilinx Relationally Placed Mac­ros (RPMs) that already include these symbols.
X6687
CLB CLB CLB CLB
CLB CLB CLB CLB
CLB
CLB
CLB
CLB
CLB
CLB
CLB
CLB
Figure 11: Available XC4000E Carry Propagation Paths
X6610
CLB CLB CLB CLB
CLB CLB CLB CLB
CLB
CLB
CLB
CLB
CLB
CLB
CLB
CLB
Figure 12: Available XC4000X Carry Propagation Paths (dotted lines use general interconnect)
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May 14, 1999 (Version 1.6) 6-19
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
DQ
S/R
EC
YQ
Y
DIN
H G
F
G
H
DQ
S/R
EC
XQ
DIN
H G
F
H
X
H
F
G
G4
G3
G2
G1
F
F3
F2
F1
F4
F
CARRY
G
CARRY
C
C
DOWN
CARRY
LOGIC
D
CC
UP
K S/R EC
H1
X6699
OUT
IN
OUT
IN
IN
C
OUT0
Figure 13: Fast Carry Logic in XC4000E CLB (shaded area not present in XC4000X)
R
XC4000E and XC4000X Series Field Programmable Gate Arrays
6-20 May 14, 1999 (Version 1.6)
Input/Output Blocks (IOBs)
User-configurable input/output blocks (IOBs) provide the interface between external package pins and the internal logic. Each IOB controls one package pin and can be con­figured for input, output, or bidirectional signals.
Figure 15 shows a simplified block diagram of the
XC4000E IOB. A more complete diagram which includes the boundary scan logic of the XC4000E IOB can be found in Figure 40 on page 43, in the “Boundary Scan” section.
The XC4000X IOB contains some special features not included in the XC4000E IOB. These features are high­lighted in a simplified block diagram foundin Figure 16, and discussed throughout this section. When XC4000X special features are discussed, they are clearly identified in the text. Any feature not so identified is present in both XC4000E and XC4000X devices.
IOB Input Signals
Two paths, labeled I1 and I2 in Figure 15 and Figure 16, bring input signals into the array. Inputs also connect to an input register that can be programmed as either an edge-triggered flip-flop or a level-sensitive latch.
The choice is made by placing the appropriate library sym­bol. For example,IFDisthe basic input flip-flop (rising edge triggered), and ILD is the basic input latch (transpar­ent-High). Variations with inverted clocks are available, and some combinations of latches and flip-flops can be imple­mented in a single IOB, as described in the
XACT Libraries
Guide
.
The XC4000E inputs can be globally configured for either TTL (1.2V) or 5.0 volt CMOS thresholds, using an option in the bitstream generation software. There is a slight input hysteresis of about 300mV. The XC4000E output levels are also configurable; the two global adjustments of input threshold and output level are independent.
Inputs on the XC4000XL are TTL compatible and 3.3V CMOS compatible. Outputs on the XC4000XL are pulled to the 3.3V positive supply.
The inputs of XC4000 Series 5-Volt devices can be driven by the outputs of any 3.3-Volt device,if the 5-Voltinputs are in TTL mode.
Supported sources for XC4000 Series device inputs are shown in Table 8.
01
01
M
M
0
1
01
M
0
1
M
10
M
M
0
3
M
1
M
I
G1
G4
F2
F1
F3
C
OUT
G2
G3
F4
C
INUP
C
IN DOWN
X2000
TO FUNCTION GENERATORS
M
M
M
C
OUT0
Figure 14: Detail of XC4000E Dedicated Carry Logic
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May 14, 1999 (Version 1.6) 6-21
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
Q
Flip-
Flop/
Latch
D
D CE
CE
Q
Out
T
Output
Clock
I
Input
Clock
Clock
Enable
Delay
Pad
Flip-Flop
Slew Rate
Control
Output
Buffer
Input
Buffer
Passive Pull-Up/
Pull-Down
2
I
1
X6704
Figure 15: Simplified Block Diagram of XC4000E IOB
Q
Flip-Flop/
Latch
Fast
Capture
Latch
D
Q Latch
D
G
D
0 1
CE
CE
Q
Out
T
Output Clock
I
Input Clock
Clock Enable
Pad
Flip-Flop
Slew Rate
Control
Output
Buffer
Output MUX
Input
Buffer
Passive Pull-Up/
Pull-Down
2
I
1
X5984
Delay Delay
Figure 16: Simplified Block Diagram of XC4000X IOB (shaded areas indicate differences from XC4000E)
R
XC4000E and XC4000X Series Field Programmable Gate Arrays
6-22 May 14, 1999 (Version 1.6)
XC4000XL 5-Volt Tolerant I/Os
The I/Os on the XC4000XL are fully 5-volt tolerant even though the VCCis 3.3 volts. This allows 5 V signals to directly connect to the XC4000XL inputs without damage, as shown in Table 8. In addition, the 3.3 volt VCCcan be applied before or after 5 voltsignals are applied to the I/Os. This makes the XC4000XL immune to power supply sequencing problems.
Registered Inputs
The I1 and I2 signals that exit the block can each carry either the direct or registered input signal.
The input and output storage elements in each IOB have a common clock enable input, which, through configuration, can be activated individually for the input or output flip-flop, or both. This clock enable operates exactly like the EC pin on the XC4000 Series CLB. It cannot beinverted within the IOB.
The storage element behavior is shown in Table 9.
Table 9: Input Register Functionality (active rising edge is shown)
Optional Delay Guarantees Zero Hold Time
The data input to the register can optionally be delayed by several nanoseconds. With the delay enabled, the setup time of the input flip-flop is increased so that normal clock routing does not result in a positive hold-time requirement. A positive hold time requirement can lead to unreliable, temperature- or processing-dependent operation.
The input flip-flop setup time is defined between the data measured at the device I/O pin and the clock input at the IOB (not at the clock pin). Any routing delay from the device clock pin to the clock input of the IOB must, therefore, be subtracted from this setup time to arrive at the real setup time requirement relative to the device pins. A short speci­fied setup time might, therefore, result in a negative setup time at the device pins, i.e., a positive hold-time require­ment.
When a delay is inserted on the data line, more clock delay can be tolerated without causing a positive hold-time requirement. Sufficient delay eliminates the possibility of a data hold-time requirement at the external pin. The maxi­mum delay is therefore inserted as the default.
The XC4000E IOB has a one-tap delay element: either the delay is inserted (default), or it isnot. The delay guarantees a zero hold time with respect to clocks routed through any of the XC4000E global clock buffers.(See“Global Nets and
Buffers(XC4000E only)” on page 35 foradescriptionof the
global clock buffers in the XC4000E.) For a shorter input register setup time,with non-zero hold, attach a NODELAY attribute or property to the flip-flop.
The XC4000X IOB has a two-tap delay element, with choices of a full delay, a partial delay, or no delay. The attributes or properties used to select the desired delay are shown in Table 10. The choices are no added attribute, MEDDELAY, and NODELAY. The default setting, with no added attribute, ensures no hold timewith respect to any of the XC4000X clock buffers,including the Global Low-Skew buffers. MEDDELAY ensures no hold time with respect to the Global Early buffers. Inputs with NODELAYmayhavea positive hold time with respect to all clock buffers. For a description of each of these buffers, see “Global Nets and
Buffers (XC4000X only)” on page 37.
Table 10: XC4000X IOB Input Delay Element
Table 8: Supported Sources for XC4000 Series Device Inputs
Source
XC4000E/EX
Series Inputs
XC4000XL
Series Inputs
5 V,
TTL
5 V,
CMOS
3.3 V
CMOS
Any device, Vcc = 3.3 V, CMOS outputs
Unreli
-able Data
XC4000 Series, Vcc = 5 V, TTL outputs
√√
Any device, Vcc = 5 V, TTL outputs (Voh 3.7 V)
√√
Any device, Vcc = 5 V, CMOS outputs
√√
Mode Clock
Clock
Enable
DQ
Power-Up or GSR
XXXSR
Flip-Flop __/
1* D D
0XXQ
Latch 1 1* X Q
01*DD
Both X 0 X Q
Legend:
X __/ SR
0* 1*
Don’t care Rising edge Set or Reset value. Reset is default. Input is Low or unconnected (default value) Input is High or unconnected (default value)
Value When to Use
full delay (default, no attribute added)
Zero Hold with respect to Global Low-Skew Buffer, Global Early Buffer
MEDDELAY ZeroHold with respecttoGlobal Early
Buffer
NODELAY Short Setup, positive Hold time
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May 14, 1999 (Version 1.6) 6-23
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
Additional Input Latch for FastCapture (XC4000X only)
The XC4000X IOB has an additional optional latch on the input. This latch, as shown in Figure 16, is clocked by the output clock — the clock used for the output flip-flop — rather than the input clock. Therefore, two different clocks can be used to clock the two input storage elements. This additional latch allows the very fast capture of input data, which is then synchronized to the internal clock by the IOB flip-flop or latch.
To use this Fast Capture technique, drive the output clock pin (the FastCapturelatchingsignal)fromtheoutput of one of the Global Early buffers supplied in the XC4000X. The second storage element should be clocked by a Global Low-Skew buffer, to synchronize the incoming data to the internal logic. (See Figure 17.) These special buffers are described in “Global Nets and Buffers (XC4000X only)” on
page 37.
The Fast Capture latch (FCL) is designed primarily for use with a Global Early buffer. For Fast Capture, a single clock signal is routed through both a Global Early buffer and a Global Low-Skew buffer. (The two buffers share an input pad.) The Fast Capture latch is clocked by the Global Early buffer, and the standard IOB flip-flop or latch is clocked by the Global Low-Skew buffer.This mode is the safest way to use the Fast Capture latch, because the clock buffers on both storageelementsaredrivenbythesamepad.Thereis no external skew between clock pads to create potential problems.
To place the Fast Capture latch in a design, use one of the special library symbols, ILFFX or ILFLX. ILFFX is a trans­parent-Low Fast Capture latch followed by an active-High input flip-flop. ILFLX is a transparent-Low Fast Capture latch followed by a transparent-High input latch. Any of the clock inputs can be inverted before driving the library ele­ment, and the inverter is absorbed into the IOB. If a single BUFG output is used to drive both clock inputs, the soft­ware automatically runs the clock through both a Global Low-Skew buffer and a Global Early buffer, and clocks the Fast Capture latch appropriately.
Figure 16 on page 21 also shows a two-tap delay on the
input. By default, if the Fast Capture latch is used, the Xilinx software assumes a Global Early bufferis driving the clock, and selects MEDDELAY to ensure a zero hold time. Select
the desired delay based on the discussion in the previous subsection.
IOB Output Signals
Output signals can be optionally inverted within the IOB, and can pass directly to the pad or be stored in an edge-triggered flip-flop. The functionality of this flip-flop is shown in Table 11.
An active-High 3-state signal can be used to place the out­put buffer in a high-impedance state, implementing 3-state outputs or bidirectional I/O. Under configuration control, the output (OUT) and output 3-state (T) signals can be inverted. The polarity of these signals is independently con­figured for each IOB.
The 4-mA maximum output current specification of many FPGAs often forces the user to add external buffers, which are especially cumbersome on bidirectional I/O lines. The XC4000E and XC4000EX/XL devices solve many of these problems by providing a guaranteed output sink current of 12 mA. Two adjacent outputs can be interconnected exter­nally to sink up to 24 mA. The XC4000E and XC4000EX/XL FPGAs can thus directly drive buses on a printed circuit board.
By default, the output pull-up structure is configured as a TTL-liketotem-pole.TheHighdriverisann-channelpull-up transistor, pulling to a voltage one transistor threshold below Vcc. Alternatively, the outputs can beglobally config­ured as CMOS drivers, with p-channel pull-up transistors pulling to Vcc. This option,applied using the bitstream gen­eration software, applies to all outputs on the device. It is not individually programmable. In the XC4000XL, all out­puts are pulled to the positive supply rail.
IPAD
IPAD
BUFGE
BUFGLS
C
CE
DQ
GF
to internal logic
ILFFX
X9013
Figure 17: Examples Using XC4000X FCL
Table 11: Output Flip-Flop Functionality (active rising edge is shown)
Mode Clock
Clock
Enable T D Q
Power-Up or GSR
X X 0* X SR
Flip-Flop
X00*XQ
__/
1* 0* D D
XX1XZ
0X0*XQ
Legend:
X __/ SR
0* 1*
Z
Don’t care Rising edge Set or Reset value. Reset is default. Input is Low or unconnected (default value) Input is High or unconnected (default value) 3-state
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XC4000E and XC4000X Series Field Programmable Gate Arrays
6-24 May 14, 1999 (Version 1.6)
Any XC4000 Series 5-Volt device with its outputs config­ured in TTL mode can drive the inputs of any typical
3.3-Volt device. (For a detailed discussion of how to inter­face between 5 V and 3.3 V devices, see the 3V Products section of
The Programmable Logic Data Book
.)
Supported destinations for XC4000 Series device outputs are shown in Table 12.
An output can be configured as open-drain (open-collector) by placing an OBUFT symbol in a schematic or HDL code, then tying the 3-state pin (T) to the output signal, and the input pin (I) to Ground. (See Figure 18.)
Table 12: Supported Destinations for XC4000 Series Outputs
Output Slew Rate
The slew rate of each output buffer is, by default, reduced, to minimize power bus transients when switching non-criti­cal signals. For critical signals, attach a FAST attribute or property to the output buffer or flip-flop.
For XC4000E devices, maximum total capacitive load for simultaneous fast mode switching in the same direction is 200 pF for all package pins between each Power/Ground pin pair. For XC4000X devices, additional internal
Power/Ground pin pairs are connected to special Power and Ground planes within the packages, to reduce ground bounce. Therefore, the maximum total capacitive load is 300 pF between each external Power/Ground pin pair. Maximum loading may vary for the low-voltage devices.
Forslew-ratelimitedoutputs this total is two times larger for each device type: 400 pF for XC4000E devices and 600 pF for XC4000X devices. This maximum capacitive load should not be exceeded, as it can result in ground bounce of greater than 1.5 V amplitude and more than 5 ns dura­tion. This level of ground bounce may cause undesired transient behavior on an output, or in the internal logic. This restriction is common to all high-speed digital ICs, and is not particular to Xilinx or the XC4000 Series.
XC4000 Series devices have a feature called “Soft Start-up,” designed to reduce ground bounce when all out­puts are turned on simultaneously at the end of configura­tion. When the configuration process is finished and the device starts up, the first activation of the outputs is auto­matically slew-rate limited. Immediately following the initial activation of the I/O, the slew rate of the individual outputs is determined by the individual configurationoptionforeach IOB.
Global Three-State
A separate Global 3-State line (not shown in Figure 15 or
Figure 16) forces all FPGA outputs to the high-impedance
state, unless boundary scan is enabled and is executing an EXTEST instruction. This global net (GTS) does not com­pete with other routing resources; ituses a dedicated distri­bution network.
GTS can be driven from any user-programmable pin as a global 3-state input. To use this global net, place an input pad and input buffer in the schematic or HDL code, driving the GTS pin of the STARTUP symbol. A specific pin loca­tion can be assigned to this input using a LOC attribute or property,justaswithanyotheruser-programmablepad.An inverter can optionally be inserted after the input buffer to invert the sense of the Global 3-State signal. Using GTS is similar to GSR. See Figure 2 on page 11 for details.
Alternatively, GTS can be driven from any internal node.
Destination
XC4000 Series
Outputs
3.3 V,
CMOS
5 V,
TTL
5 V,
CMOS
Any typical device,Vcc=3.3V, CMOS-threshold inputs
√√some
1
1. Only if destination device has 5-V tolerant inputs
Any device, Vcc = 5 V, TTL-threshold inputs
√√√
Any device, Vcc = 5 V, CMOS-threshold inputs
Unreliable
Data
X6702
OPAD
OBUFT
Figure 18: Open-Drain Output
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May 14, 1999 (Version 1.6) 6-25
XC4000E and XC4000X Series Field Programmable Gate Arrays
6
Output Multiplexer/2-Input Function Generator (XC4000X only)
As shown in Figure 16 on page 21, the output path in the XC4000X IOB contains an additional multiplexer not avail­able in the XC4000E IOB. The multiplexer can also be con­figured as a 2-input function generator, implementing a pass-gate,AND-gate,OR-gate,orXOR-gate,with0,1,or2 inverted inputs. The logic used to implement these func­tions is shown in the upper gray area of Figure 16.
When configured as a multiplexer, this feature allows two output signals to time-share the same output pad; effec­tively doubling the number of device outputs without requir­ing a larger, more expensive package.
When the MUX is configured as a 2-input function genera­tor, logic can be implemented within the IOB itself. Com­bined with a Global Early buffer, this arrangement allows very high-speed gating of a single signal. For example, a wide decoder can be implemented in CLBs, and its output gated with a Read or Write Strobe Driven by a BUFGE buffer, as shown in Figure 19. The critical-path pin-to-pin delay of this circuit is less than 6 nanoseconds.
As shown in Figure 16, the IOB input pins Out, Output Clock, and Clock Enable have different delays and different flexibilities regarding polarity. Additionally, Output Clock sources are more limited than the other inputs. Therefore, the Xilinx software does not move logic into the IOB func­tion generators unless explicitly directed to do so.
The user can specify that the IOB function generator be used, by placing special library symbols beginning with the letter “O.” Forexample, a 2-input AND-gate in the IOB func­tion generator is called OAND2. Use the symbol input pin labelled “F” for the signal on the critical path. This signal is placed on the OK pin — the IOB input with the shortest delay to the function generator. Two examples are shown in
Figure 20.
Other IOB Options
There are a number of other programmable options in the XC4000 Series IOB.
Pull-up and Pull-down Resistors
Programmable pull-up and pull-down resistors are useful for tying unused pins to Vcc or Ground to minimize power consumption and reduce noise sensitivity.Theconfigurable pull-up resistor is a p-channel transistor that pulls to Vcc. The configurable pull-down resistor is an n-channel transis­tor that pulls to Ground.
The value of these resistors is 50 kΩ−100 kΩ. This high value makes them unsuitable as wired-AND pull-up resis­tors.
The pull-up resistors for most user-programmable IOBs are active during the configuration process. See Table 22 on
page 58 for a list of pins with pull-ups active before and dur-
ing configuration. After configuration, voltage levels of unused pads, bonded
or un-bonded, must be valid logic levels, to reduce noise sensitivity and avoid excess current. Therefore, by default, unused pads are configured with the internal pull-up resis­tor active. Alternatively, they can be individually configured with the pull-down resistor, or as a driven output, or to be driven by an external source. To activate the internal pull-up, attach the PULLUP library component to the net attached to the pad. To activate the internal pull-down, attach the PULLDOWN library component to the net attached to the pad.
Independent Clocks
Separate clocksignalsareprovidedfortheinputandoutput flip-flops. The clock can be independently inverted for each flip-flop within the IOB, generating either falling-edge or ris­ing-edge triggered flip-flops. The clock inputs for each IOB are independent, except that in the XC4000X, the Fast Capture latch shares an IOB input withtheoutput clock pin.
Early Clock for IOBs (XC4000X only)
Special early clocks are available for IOBs. These clocks are sourced by the same sources as the Global Low-Skew buffers,but are separately buffered.They have fewer loads and therefore less delay. The early clock can drive either the IOB output clock or the IOB input clock, or both. The early clock allows fast capture of input data, and fast clock-to-output on output data. The Global Early buffers that drive these clocks are described in “Global Nets and
Buffers (XC4000X only)” on page 37.
Global Set/Reset
As with the CLB registers, the Global Set/Reset signal (GSR) can be used to set or clear the input and output reg­isters, depending on the value of the INIT attribute or prop­erty. The two flip-flops can be individually configured to set
IPAD
F
OPAD
FAST
BUFGE
OAND2
from internal logic
X9019
Figure 19: Fast Pin-to-Pin Path in XC4000X
OAND2
F
X6598
D0
S0
D1
O
OMUX2
X6599
Figure 20: AND & MUX Symbols in XC4000X IOB
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