XC2V8000-4FF1517I Xilinx Inc, XC2V8000-4FF1517I Datasheet - Page 36

XC2V8000-4FF1517I

Manufacturer Part Number

XC2V8000-4FF1517I

Description

IC FPGA VIRTEX-II 1517FCBGA

Manufacturer

Xilinx Inc

Series

Virtex™-IIr

Datasheet

1.XC2V250-4FGG256C.pdf (318 pages)

Specifications of XC2V8000-4FF1517I

Number Of Labs/clbs

11648

Total Ram Bits

3096576

Number Of I /o

1108

Number Of Gates

8000000

Voltage - Supply

1.425 V ~ 1.575 V

Mounting Type

Surface Mount

Operating Temperature

-40°C ~ 100°C

Package / Case

1517-BBGA, FCBGA

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Number Of Logic Elements/cells

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The most common configuration option of this element is as

a buffer. A BUFG function in this (global buffer) mode, is

shown in

The Virtex-II global clock buffer BUFG can also be config-

ured as a clock enable/disable circuit

a two-input clock multiplexer

description of these two options is provided below. Each of

DS031-2 (v3.5) November 5, 2007

Product Specification

Figure 39: Virtex-II Clock Distribution Configurations

Figure

Clock Distribution

Figure 41: Virtex-II BUFG Function

Buffer

Clock

Pad

41.

BUFG

DS031_61_101200

(Figure

8 BUFGMUX

16 Clocks

8 BUFGMUX

Clock Distribution

(Figure

CLKOUT

Buffer

DS031_43_101000

CLKIN

DCM

Clock

43). A functional

Pad

Figure 40: Virtex-II Clock Distribution

42), as well as

www.xilinx.com

Global clock buffers are used to distribute the clock to some

or all synchronous logic elements (such as registers in

CLBs and IOBs, and SelectRAM blocks.

Eight global clocks can be used in each quadrant of the

Virtex-II device. Designers should consider the clock distri-

bution detail of the device prior to pin-locking and floorplan-

ning (see the Virtex-II User Guide).

Figure 40

In each quadrant, up to eight clocks are organized in clock

rows. A clock row supports up to 16 CLB rows (eight up and

eight down). For the largest devices a new clock row is

added, as necessary.

To reduce power consumption, any unused clock branches

remain static.

Global clocks are driven by dedicated clock buffers (BUFG),

which can also be used to gate the clock (BUFGCE) or to mul-

tiplex between two independent clock inputs (BUFGMUX).

them can be used in either of two modes, selected by con-

figuration: rising clock edge or falling clock edge.

This section describes the rising clock edge option. For the

opposite option, falling clock edge, just change all "rising"

references to "falling" and all "High" references to "Low",

except for the description of the CE or S levels. The rising

clock edge option uses the BUFGCE and BUFGMUX prim-

itives. The falling clock edge option uses the BUFGCE_1

and BUFGMUX_1 primitives.

BUFGCE

If the CE input is active (High) prior to the incoming rising

clock edge, this Low-to-High-to-Low clock pulse passes

through the clock buffer. Any level change of CE during the

incoming clock High time has no effect.

8 BUFGMUX

Virtex-II Platform FPGAs: Functional Description

16 Clocks

shows clock distribution in Virtex-II devices.

DS031_45_120200

8 max

Module 2 of 4

XC2V8000-4FF1517I Xilinx Inc, XC2V8000-4FF1517I Datasheet - Page 36

XC2V8000-4FF1517I

Specifications of XC2V8000-4FF1517I

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