XC4VFX60-10FFG1152C Xilinx Inc, XC4VFX60-10FFG1152C Datasheet - Page 72

XC4VFX60-10FFG1152C

Manufacturer Part Number

XC4VFX60-10FFG1152C

Description

IC FPGA VIRTEX-4 FX 60K 1152FBGA

Manufacturer

Xilinx Inc

Series

Virtex™-4r

Datasheets

1.XC4VFX12-10FFG668C.pdf (58 pages)

2.XC4VFX12-10FFG668C.pdf (9 pages)

3.XC4VFX12-10FFG668C.pdf (406 pages)

Specifications of XC4VFX60-10FFG1152C

Total Ram Bits

4276224

Number Of Logic Elements/cells

56880

Number Of Labs/clbs

6320

Number Of I /o

576

Voltage - Supply

1.14 V ~ 1.26 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

1152-BBGA, FCBGA

No. Of Logic Blocks

6656

No. Of Macrocells

56880

Family Type

Virtex-4

No. Of Speed Grades

No. Of I/o's

576

Clock Management

DCM

Core Supply

RoHS Compliant

Package

1152FCBGA

Family Name

VirtexÂ®-4

Device Logic Units

56880

Typical Operating Supply Voltage

1.2 V

Maximum Number Of User I/os

576

Ram Bits

4276224

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

HW-V4-ML410-UNI-G - EVALUATION PLATFORM VIRTEX-4

Number Of Gates

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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XC4VFX60-10FFG1152C

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Part Number:

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Manufacturer:

Xilinx Inc

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Company:

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Part Number:

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Part Number:

XC4VFX60-10FFG1152C

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Chapter 2: Digital Clock Managers (DCMs)

Output Clocks

DCM During Configuration and Startup

clock is restored. Thus, a High on LOCKED does not necessarily mean that a valid clock is

available.

When stopping the input clock (CLKIN remains High or Low for one or more clock cycles),

one to nine more output clock cycles are still generated as the delay line is flushed. When

the output clock stops, the CLKIN stopped (DO[1]) signal is asserted. When the clock is

restarted, the output clock cycles are not generated for one to eight clocks while the delay

line is filled. Similarly, the DO[1] signal is deasserted once the output clock is generated.

The most common case is two or three clocks. CLKIN can be restarted with any phase

relationship to the previous clock. If the frequency has changed, the DCM requires a reset.

The DO[1] is forced Low whenever LOCKED is Low. When the DCM is in the locking

process, DO[1] status is held Low until LOCKED is achieved.

Any or all of the DCM’s nine clock outputs can be used to drive a global clock network.

The fully-buffered global clock distribution network minimizes clock skew caused by

loading differences. By monitoring a sample of the output clock (CLK0), the deskew circuit

compensates for the delay on the routing network, effectively eliminating the delay from

the external input port to the individual clock loads within the device.

All DCM outputs can drive general interconnect; however, these connections are not

suitable for critical clock signals. It is recommended that all clock signals should be within

the global or regional clock network. Refer to

information on using clock networks.

Output pin connectivity carries some restrictions. The DCM clock outputs can each drive

an OBUF, a global clock buffer BUFGCTRL, or they can route directly to the clock input of

a synchronous element. To use dedicated routing, the DCM clock outputs must drive

BUFGCTRLs on the same top or bottom half of the device. If the DCM and BUFGCTRL are

not on the same top or bottom half, local routing is used and the DCM might not deskew

properly.

Do not use the DCM output clock signals until after activation of the LOCKED signal. Prior

to the activation of the LOCKED signal, the DCM output clocks are not valid.

During the FPGA configuration, the DCM is in reset and starts to lock at the beginning of

the startup sequence. A DCM requires both CLKIN and CLKFB input clocks to be present

and stable when the DCM begins to lock. If the device enters the configuration startup

sequence without an input clock, or with an unstable input clock, then the DCM must be

reset after configuration with a stable clock.

The following startup cycle dependencies are of note:

The default value is -g LCK_cycle:NoWait. When this setting is used, the startup

sequence does not wait for the DCM to lock. WHen the LCK_cycle is set to other

values, the configuration startup remains in the specified startup cycle until the DCM

is locked.

Before setting the LCK_cycle option to a startup cycle in BitGen, the DCM’s

STARTUP_WAIT attribute must be set to TRUE.

If the startup sequence is altered (by using the BitGen option), do not place the

LCK_cycle (wait for the DCM to lock) before the GTS_cycle (deassert GTS). Incorrect

implementation will result in the DCM not locking and an incomplete configuration.

www.xilinx.com

Chapter 1, “Clock Resources”

UG070 (v2.6) December 1, 2008

Virtex-4 FPGA User Guide

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XC4VFX60-10FFG1152C Xilinx Inc, XC4VFX60-10FFG1152C Datasheet - Page 72

XC4VFX60-10FFG1152C

Specifications of XC4VFX60-10FFG1152C

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