XC4VFX12-10SFG363C Xilinx Inc, XC4VFX12-10SFG363C Datasheet - Page 105

XC4VFX12-10SFG363C

Manufacturer Part Number

XC4VFX12-10SFG363C

Description

IC FPGA VIRTEX-4 FX 12K 363FCBGA

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 XC4VFX12-10SFG363C

Number Of Logic Elements/cells

12312

Number Of Labs/clbs

1368

Total Ram Bits

663552

Number Of I /o

240

Voltage - Supply

1.14 V ~ 1.26 V

Mounting Type

Surface Mount

Operating Temperature

0°C ~ 85°C

Package / Case

363-FBGA, FCBGA

Package

363FCBGA

Family Name

VirtexÂ®-4

Device Logic Units

12312

Typical Operating Supply Voltage

1.2 V

Maximum Number Of User I/os

240

Ram Bits

663552

For Use With

HW-V4-ML403-UNI-G - EVALUATION PLATFORM VIRTEX-4

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Number Of Gates

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

XC4VFX12-10SFG363C

Manufacturer:

Xilinx Inc

Quantity:

10 000

Company:

BOSTOCK HK LIMITED

Part Number:

XC4VFX12-10SFG363C

Manufacturer:

XILINX

Current page: 105 of 406
Download datasheet (6Mb)

Virtex-4 FPGA User Guide

UG070 (v2.6) December 1, 2008

Connecting PMCD to other Clock Resources

IBUFG to PMCD

DCM to PMCD

BUFGCTRL to PMCD

Figure 3-6

In most applications, the PMCD is used with other clock resources including dedicated

clock I/O (IBUFG), clock buffers (BUFGCTRLs), DCMs, and an MGT clock. Additionally,

PMCD inputs and outputs can be connected to the general interconnects. This section

provides guidelines on connecting a PMCD to clock resources using dedicated routing.

Virtex-4 devices contain 16 or 32 global clock I/Os. These clock I/Os are accessible by

instantiating the IBUFG component. Each top and bottom half of the center column

contains eight or 16 IBUFGs. Any of the IBUFGs in the top or bottom half can drive the

clock input pins (CLKA, CLKB, CLKC, or CLKD) of a PMCD located in the same

top/bottom half. The routing from multiple IBUFGs to PMCD inputs are not matched.

Any DCM clock output can drive any PMCD input in the same top/bottom half of the

device. A DCM can drive parallel PMCDs in the same group of two. It is not advisable to

drive parallel PMCDs with DCMs in different groups of two (on the same top/bottom

half) because there can be significant skew between PMCD outputs. This skew is caused by

the skew between inputs of PMCDs in different groups.

Any BUFGCTRL can drive any Virtex-4 FPGA PMCD. However, only up to eight

dedicated global clock routing resources exist in a particular clock region. Therefore, access

to PMCD inputs via a BUFGCTRL is limited to eight unique signals. Other resources in the

clock region will compete for the eight global clock tracks.

CLKA1D(2, 4, 8)

CLKA1

CLKA

Deasserted RST

RST

REL

illustrates the interaction between the RST and REL signals.

is registered.

Delayed output clocks start toggling.

Figure 3-6: REL Waveform Example

www.xilinx.com

PMCD Usage and Design Guidelines

Release is synchronized.

Divided output clocks start toggling.

RST_DEASSERT_CLK = CLKA

EN_REL = TRUE

UG070_3_06_071404

105

XC4VFX12-10SFG363C Xilinx Inc, XC4VFX12-10SFG363C Datasheet - Page 105

XC4VFX12-10SFG363C

Specifications of XC4VFX12-10SFG363C

Available stocks

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