SI5020-EVB Datasheet, PDF(2/12 Page) Silicon Laboratories

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SI5020-EVB Datasheet, PDF (2/12 Pages) Silicon Laboratories – Simple jumper configuration

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Si5020-EVB

Functional Description

The evaluation board simplifies characterization of the

Si5020 Clock and Data Recovery (CDR) device by

providing access to all of the Si5020 I/Os. Device

performance can be evaluated by following the Test

Configuration section below. Specific performance

metrics include jitter tolerance, jitter generation, and

jitter transfer.

Power Supply

The evaluation board requires one 2.5 V supply. Supply

filtering is placed on the board to filter typical system

noise components, however, initial performance testing

should use a linear supply capable of supplying 2.5 V

Â±5% dc.

CAUTION: The evaluation board is designed so that the

body of the SMA jacks and GND are shorted. Care must

be taken when powering the PCB at potentials other

than GND at 0.0 V and VDD at 2.5 V relative to chassis

GND.

Self-Calibration

The Si5020 device provides an internal self-calibration

function that optimizes the loop gain parameters within

the internal DSPLLTM. Self-calibration is initiated by a

high-to-low transition of the PWRDN/CAL signal while a

valid reference clock is supplied to the REFCLK input.

On the Si5020-EVB board, a voltage detector IC is

utilized to initiate self-calibration. The voltage detector

drives the PWRDN/CAL signal low after the supply

voltage has reached a specific voltage level. This circuit

is described in Silicon Laboratories application note

AN42. On the Si5020-EVB, the PWRDN/CAL signal is

also accessible via a jumper located in the lower left-

hand corner of the evaluation board. PWRDN/CAL is

wired to the signal post adjacent to the 2.5 V post.

Device Powerdown

The CDR can be powered down via the PWRDN/CAL

signal. When asserted the evaluation board will draw

minimal current. PWRDN/CAL is controlled via one

jumper located in the lower left-hand corner of the

evaluation board. PWRDN/CAL is wired to the signal

post adjacent to the 2.5 V post.

CLKOUT, DATAOUT, DATAIN

These high-speed I/Os are wired to the board perimeter

on 30 mil (0.030 inch) 50 ï microstrip lines to the end-

launch SMA jacks as labeled on the PCB. These I/Os

are AC coupled to simplify direct connection to a wide

array of standard test hardware. Because each of these

signals are differential both the positive (+) and negative

(â) terminals must be terminated to 50 ï. Terminating

only one side will adversely degrade the performance of

the CDR. The inputs are terminated on the die with 50 ï

resistors.

To improve the DATAOUT eye-diagram, short 100 ï

transmission line segments precede the 50 ï high-

speed traces. These segments increase the interface

bandwidth from the chip to the 50 ï traces and reduce

data inter-symbol-interference. Please refer to Silicon

Laboratories application note AN43 for more details.

Note: The 50 ï termination is for each terminal/side of a dif-

ferential signal, thus the differential termination is actu-

ally 50 ï + 50 ï = 100 ï.

REFCLK

REFCLK is used to center the frequency of the

DSPLLâ¢ so that the device can lock to the data. Ideally

the REFCLK frequency should be 1/128th, 1/32nd, or

1/16th the VCO frequency and must have a frequency

accuracy of Â±100 PPM. Internally, the CDR

automatically recognizes the REFCLK frequency within

one of these three frequency ranges. Typical REFCLK

frequencies are given in Table 1. REFCLK is AC

coupled to the SMA jacks located on the top side of the

evaluation board.

Table 1. Typical REFCLK Frequencies

SONET/SDH

Gigabit

Ethernet

19.44 MHz

77.76 MHz

155.52 MHz

19.53 MHz

78.125 MHz

156.25 MHz

SONET/

SDH with

15/14 FEC

20.83 MHz

83.31 MHz

166.63 MHz

Ratio of

VCO to

REFCLK

128

RATESEL

RATESEL is used to configure the CDR to recover clock

and data at different data rates. RATESEL is a two bit

binary input that is controlled via two jumpers located in

the lower left-hand corner of the evaluation board.

RATESEL0/1 are wired to the center posts (signal post)

between 2.5 V and GND. For example, the OC-48 data

rate is selected by jumping RATESEL0 to 0.0 V and

RATESEL1 to 0.0 V.

The table given on the evaluation board lists

approximate data rates for the jumper configurations

shown in Figure 1. Applications with data rates within

Â±7% of the given data rate are also accommodated.

Rev. 1.0

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