HW-V5-ML506-UNI-G Xilinx Inc, HW-V5-ML506-UNI-G Datasheet - Page 19

HW-V5-ML506-UNI-G

Manufacturer Part Number

HW-V5-ML506-UNI-G

Description

EVALUATION PLATFORM VIRTEX-5

Manufacturer

Xilinx Inc

Series

Virtex™-5 SXTr

Type

DSPr

Datasheet

1.HW-V5-ML507-UNI-G.pdf (60 pages)

Specifications of HW-V5-ML506-UNI-G

Contents

Evaluation Platform, DVI Adapter and CompactFlash Card

Silicon Manufacturer

Xilinx

Features

JTAG Programming Interface, Platform Flash, External Clocking

Kit Contents

Board, Cable, PSU, CD, Docs

Silicon Family Name

Virtex-5

Silicon Core Number

XC5VSX50TFFG1136

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With/related Products

XC5VSX50TFFG1136

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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Part Number:

HW-V5-ML506-UNI-G

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ML505/ML506/ML507 Evaluation Platform

UG347 (v3.1.1) October 7, 2009

3. Differential Clock Input and Output with SMA Connectors

4. Oscillators

DDR2 Memory Expansion

DDR2 Clock Signal

DDR2 Signaling

The DDR2 interface support user installation of SODIMM modules with more memory

since higher order address and chip select signals are also routed from the SODIMM to the

FPGA.

Two matched length pairs of DDR2 clock signals are broadcast from the FPGA to the

SODIMM. The FPGA design is responsible for driving both clock pairs with low skew. The

delay on the clock trace is designed to match the delay of the other DDR2 control signals.

All DDR2 SDRAM control signals are terminated through 47Ω resistors to a 0.9V VTT

reference voltage. The FPGA DDR2 interface supports SSTL18 signaling and all DDR2

signals are controlled impedance. The DDR2 data, mask, and strobe signals are matched

length within byte groups. The ODT functionality of the SODIMM should be utilized.

High-precision clock signals can be input to the FPGA using differential clock signals

brought in through 50Ω SMA connectors. This allows an external function generator or

other clock source to drive the differential clock inputs that directly feed the global clock

input pins of the FPGA. The FPGA can be configured to present a 100Ω termination

impedance.

A differential clock output from the FPGA is driven out through an LVDS clock

multiplexer (U12) onto a second pair of SMA connectors (J12 and J13). This allows the

FPGA to drive a precision clock to an external device such as a piece of test equipment.

Table 1-3

Table 1-3: Differential SMA Clock Connections

The board has one crystal oscillator socket (X1) wired for standard LVTTL-type oscillators.

It connects to the FPGA clock pin as shown in

populated with a 100-MHz oscillator and is powered by the 3.3V supply.

The board also provides an IDT5V9885 (U8) EEPROM programmable clock generator

device. This device is used to generate a variety of clocks to the board peripherals and

Notes:

1. When jumper J54 (located near the battery) is not shunted (default), the FPGA differential clock output

Connector

is selected on U12 and driven out to the SMA connectors, J12 and J13.

J12

J13

J10

J11

(1)

summarizes the differential SMA clock pin connections.

SMA_DIFF_CLK_IN_P

SMA_DIFF_CLK_IN_N

SMA_DIFF_CLK_OUT_P

SMA_DIFF_CLK_OUT_N

Clock Name

www.xilinx.com

FPGA Pin

H14

H15

J20

J21

Table 1-4, page

GTP1 of

GTP_X0Y4

receive pair

GTP1 of

GTP_X0Y4

transmit pair

ML505/ML506

20. The X1 socket is

Detailed Description

GTX1 of

GTX_X0Y5

receive pair

GTX1 of

GTX_X0Y5

transmit pair

ML507

HW-V5-ML506-UNI-G Xilinx Inc, HW-V5-ML506-UNI-G Datasheet - Page 19

HW-V5-ML506-UNI-G

Specifications of HW-V5-ML506-UNI-G

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