XC4005A-6PC84C Xilinx Inc, XC4005A-6PC84C Datasheet - Page 11

XC4005A-6PC84C

Manufacturer Part Number

XC4005A-6PC84C

Description

IC LOGIC CL ARRAY 5000GAT 84PLCC

Manufacturer

Xilinx Inc

Series

XC4000r

Datasheet

1.XC4003-6PQ100C.pdf (40 pages)

Specifications of XC4005A-6PC84C

Number Of Logic Elements/cells

466

Number Of Labs/clbs

196

Total Ram Bits

6272

Number Of I /o

Number Of Gates

5000

Voltage - Supply

4.75 V ~ 5.25 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

84-LCC (J-Lead)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

122-1051

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comparators, counters, data registers, decoders, encod-

ers, I/O functions, latches, Boolean functions, RAM and

ROM memory blocks, multiplexers, shift registers, and

barrel shifters.

Designing with macros is as easy as designing with

standard SSI/MSI functions. The ‘soft macro’ library con-

tains detailed descriptions of common logic functions, but

does not contain any partitioning or routing information.

The performance of these macros depends, therefore, on

how the PPR software processes the design. Relationally

Placed Macros (RPMs), on the other hand, do contain pre-

determined partitioning and relative placement informa-

tion, resulting in an optimized implementation for these

functions. Users can create their own library elements –

either soft macros or RPMs – based on the macros and

primitives of the standard library.

X-BLOX is a graphics-based high-level description lan-

guage (HDL) that allows designers to use a schematic

editor to enter designs as a set of generic modules. The X-

BLOX compiler optimizes the modules for the target de-

vice architecture, automatically choosing the appropriate

architectural resources for each function.

The XACT design environment supports hierarchical de-

sign entry, with top-level drawings defining the major

functional blocks, and lower-level descriptions defining the

logic in each block. The implementation tools automati-

cally combine the hierarchical elements of a design. Differ-

ent hierarchical elements can be specified with different

design entry tools, allowing the use of the most convenient

entry method for each portion of the design.

Design Implementation

The design implementation tools satisfy the requirement

for an automated design process. Logic partitioning, block

placement and signal routing, encompassing the design

implementation process, are performed by the Partition,

Place, and Route program (PPR). The partitioner takes the

logic from the entered design and maps the logic into the

architectural resources of the FPGA (such as the logic

blocks, I/O blocks, 3-state buffers, and edge decoders).

The placer then determines the best locations for the

blocks, depending on their connectivity and the required

performance. The router finally connects the placed blocks

together. The PPR algorithms result in the fully automatic

implementation of most designs. However, for demanding

applications, the user may exercise various degrees of

control over the automated implementation process. Op-

tionally, user-designated partitioning, placement, and rout-

ing information can be specified as part of the design entry

process. The implementation of highly-structured designs

can greatly benefit from the basic floorplanning techniques

familiar to designers of large gate arrays.

The PPR program includes XACT-Performance, a feature

that allows designers to specify the timing requirements

2-17

along entire paths during design entry. Timing path analy-

sis routines in PPR then recognize and accommodate the

user-specified requirements. Timing requirements can be

entered on the schematic in a form directly relating to the

system requirements (such as the targeted minimum clock

frequency, or the maximum allowable delay on the data

path between two registers). So, while the timing of each

individual net is not predictable (nor does it need to be), the

overall performance of the system along entire signal

paths is automatically tailored to match user-generated

specifications.

The automated implementation tools are complemented

by the XACT Design Editor (XDE), an interactive graphics-

based editor that displays a model of the actual logic and

routing resources of the FPGA. XDE can be used to

directly view the results achieved by the automated tools.

Modifications can be made using XDE; XDE also performs

checks for logic connectivity and possible design-rule

violations.

Design Verification

The high development cost associated with common mask-

programmed gate arrays necessitates extensive simula-

tion to verify a design. Due to the custom nature of masked

gate arrays, mistakes or last-minute design changes can-

not be tolerated. A gate-array designer must simulate and

test all logic and timing using simulation software. Simula-

tion describes what happens in a system under worst-case

situations. However, simulation is tedious and slow, and

simulation vectors must be generated. A few seconds of

system time can take weeks to simulate.

Programmable-gate-array users, however, can use in-

circuit debugging techniques in addition to simulation.

Because Xilinx devices are reprogrammable, designs can

be verified in the system in real time without the need for

extensive simulation vectors.

The XACT development system supports both simulation

and in-circuit debugging techniques. For simulation, the

system extracts the post-layout timing information from

the design database. This data can then be sent to the

simulator to verify timing-critical portions of the design.

Back-annotation – the process of mapping the timing

information back into the signal names and symbols of the

schematic – eases the debugging effort.

For in-circuit debugging, XACT includes a serial download

and readback cable (XChecker) that connects the device

in the system to the PC or workstation through an RS232

serial port. The engineer can download a design or a

design revision into the system for testing. The designer

can also single-step the logic, read the contents of the

numerous flip-flops on the device and observe internal

logic levels. Simple modifications can be downloaded into

the system in a matter of minutes.

XC4005A-6PC84C Xilinx Inc, XC4005A-6PC84C Datasheet - Page 11

XC4005A-6PC84C

Specifications of XC4005A-6PC84C

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