XCV1600E-6BG560I Xilinx Inc, XCV1600E-6BG560I Datasheet - Page 25

XCV1600E-6BG560I

Manufacturer Part Number

XCV1600E-6BG560I

Description

IC FPGA 1.8V I-TEMP 560-MBGA

Manufacturer

Xilinx Inc

Series

Virtex™-Er

Datasheet

1.XCV200E-6CS144C.pdf (233 pages)

Specifications of XCV1600E-6BG560I

Number Of Logic Elements/cells

34992

Number Of Labs/clbs

7776

Total Ram Bits

589824

Number Of I /o

404

Number Of Gates

2188742

Voltage - Supply

1.71 V ~ 1.89 V

Mounting Type

Surface Mount

Operating Temperature

-40°C ~ 100°C

Package / Case

560-LBGA, Metal

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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the internal storage elements to begin changing state in

response to the logic and the user clock.

The relative timing of these events can be changed. In addi-

tion, the GTS, GSR, and GWE events can be made depen-

Readback

The configuration data stored in the Virtex-E configuration

memory can be readback for verification. Along with the

configuration data it is possible to readback the contents all

flip-flops/latches, LUT RAMs, and block RAMs. This capa-

Design Considerations

This section contains more detailed design information on

the following features.

•

Using DLLs

The Virtex-E FPGA series provides up to eight fully digital

dedicated on-chip Delay-Locked Loop (DLL) circuits which

provide zero propagation delay, low clock skew between

output clock signals distributed throughout the device, and

advanced clock domain control. These dedicated DLLs can

be used to implement several circuits which improve and

simplify system level design.

Introduction

As FPGAs grow in size, quality on-chip clock distribution

becomes increasingly important. Clock skew and clock

delay impact device performance and the task of managing

clock skew and clock delay with conventional clock trees

becomes more difficult in large devices. The Virtex-E series

of devices resolve this potential problem by providing up to

eight fully digital dedicated on-chip DLL circuits, which pro-

vide zero propagation delay and low clock skew between

output clock signals distributed throughout the device.

Each DLL can drive up to two global clock routing networks

within the device. The global clock distribution network min-

imizes clock skews due to loading differences. By monitor-

ing a sample of the DLL output clock, the DLL can

compensate for the delay on the routing network, effectively

eliminating the delay from the external input port to the indi-

vidual clock loads within the device.

In addition to providing zero delay with respect to a user

source clock, the DLL can provide multiple phases of the

source clock. The DLL can also act as a clock doubler or it

can divide the user source clock by up to 16.

Clock multiplication gives the designer a number of design

alternatives. For instance, a 50 MHz source clock doubled

by the DLL can drive an FPGA design operating at 100

MHz. This technique can simplify board design because the

clock path on the board no longer distributes such a

DS022-2 (v2.8) January 16, 2006

Production Product Specification

Delay-Locked Loop . . . see

BlockRAM . . . see

SelectI/O . . . see

page 31

page 24

page 19

www.xilinx.com

dent on the DONE pins of multiple devices all going High,

forcing the devices to start synchronously. The sequence

can also be paused at any stage until lock has been

achieved on any or all DLLs.

bility is used for real-time debugging. For more detailed

information, see application note XAPP138 “Virtex FPGA

Series Configuration and Readback”.

high-speed signal. A multiplied clock also provides design-

ers the option of time-domain-multiplexing, using one circuit

twice per clock cycle, consuming less area than two copies

of the same circuit. Two DLLs in can be connected in series

to increase the effective clock multiplication factor to four.

The DLL can also act as a clock mirror. By driving the DLL

output off-chip and then back in again, the DLL can be used

to deskew a board level clock between multiple devices.

In order to guarantee the system clock establishes prior to

the device “waking up,” the DLL can delay the completion of

the device configuration process until after the DLL

achieves lock.

By taking advantage of the DLL to remove on-chip clock

delay, the designer can greatly simplify and improve system

level design involving high-fanout, high-performance clocks.

Library DLL Symbols

Figure 21

symbol, BUFGDLL. This macro delivers a quick and effi-

cient way to provide a system clock with zero propagation

delay throughout the device.

the two library DLL primitives. These symbols provide

access to the complete set of DLL features when imple-

menting more complex applications.

Figure 21: Simplified DLL Macro Symbol BUFGDLL

Virtex™-E 1.8 V Field Programmable Gate Arrays

shows the simplified Xilinx library DLL macro

0ns

Figure 22

ds022_25_121099

and

Figure 23

Module 2 of 4

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XCV1600E-6BG560I Xilinx Inc, XCV1600E-6BG560I Datasheet - Page 25

XCV1600E-6BG560I

Specifications of XCV1600E-6BG560I

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