Semtech GX3290 IBIS-AMI User guide

Brand: Semtech

Model: GX3290 IBIS-AMI

Type: User guide

Semtech GX3290 IBIS-AMI is a low-power, high-speed 290×290 crosspoint switch, with robust signal conditioning circuits for driving and receiving high-speed signals through backplanes. It is designed to facilitate simulation of the GX3290 in EDA platforms compliant with IBIS 5.0. The model includes all equalization, de-emphasis, and swing settings of the GX3290. The RX model applies equalization on the signal received from a channel, and the TX model applies the analog characteristics of the GX3290 Transmit driver. The model also includes S-parameter files for the QFN package model, which extends the accuracy of the package effects beyond which can be described by R, L, and C components in the current IBIS 5.0 standard.

PDS-060931 Rev.0 December 2014

GX3290

IBIS-AMI Model

User Guide (First Draft)

PDS-060931 Rev.0 December 2014

1. Introduction

The GX3290 is a low-power, high-speed 290×290 crosspoint switch, with robust signal conditioning

circuits for driving and receiving high-speed signals through backplanes. This document describes the

contents, features, and use of the GX3290 IBIS-AMI model. The model includes all equalization, de-

emphasis and swing settings of the GX3290 and facilitates simulation of the GX3290 in EDA platforms

compliant with IBIS 5.0.

2. GX3290 IBIS-AMI Model

The GX3290 IBIS-AMI model comprises of RX and TX models. The RX model applies the equalization

on signal received from a channel. The received signal is then transmitted into another channel using the

TX model. Note that the switching core is not included in the model. Therefore, the RX and TX models

have to be used in two separate testbenches to optimize the chip different settings and board design as

shown in Figure 2-1.

Figure 2-1: The receiver and transmitter testbenches in order to use GX3290 IBIS-AMI model.

Please be advised that the receiver output signal represents the signal at the output of the on-chip equalizer

and the transmitter input is the signal after the switching core. In order to meet the receiver sensitivity

specifications, the signals at the equalizer output should have more than 100mVppd vertical eye opening.

The user should optimize the equalizer output to have the maximum vertical and horizontal eye opening.

Please note that this eye diagram will be sliced before going into the switching core and its shape is not

very important as long as it has low jitter and high vertical eye opening. The slicers have not been included

in the receiver model in order to build a linear model.

2.1 GX3290 Receiver IBIS-AMI Model

The GX3290 Receiver IBIS-AMI model consists of three parts: (1) the Analog Termination IBIS model,

(2) the Receiver AMI model and (3) the QFN package model. The block diagram in Figure 2-2 shows the

sequence of signal flow and the individual parts of the model. The external S-parameter file for the QFN

Package model extends the accuracy of the package effects beyond which can be described by R, L and C

components in the current IBIS 5.0 standard. The external S-parameter data is processed as part of the

channel by the EDA platforms.

PDS-060931 Rev.0 December 2014

Figure 2-2: GX3290 Receiver IBIS-AMI Model

2.1.1 GX3290 Receiver IBIS Model

The receiver IBIS model provides the characterized GX3290 Receiver input termination which is used by

the EDA platform to determine the time-domain impulse response for the channel. The model is based on a

single-ended non-inverting characterization of the GX3290 Receiver and the EDA platform develops a

differential model from complimentary copies of the single-ended model. Two different sub-models have

been employed for different termination modes. The appropriate sub-model has to be selected based on

EQ_termination parameter in the datasheet (page 21). Table 2-1 summarizes the use of GX3290 receiver

sub-models.

Table 2-1: Receiver sub-model selection based on EQ_termination parameter.

EQ_Termination

Input Termination Common Mode Point

Switch to VCC_IN1, VCC_IN_2

Sub-Model

Termination

Open (Figure3-1 in datasheet)

Sdi_pd0_cm25

Differential

Closed (Figure3-1 in datasheet)

Sdi_pd0_cm12

Single-Ended

Note that the IBIS model only contains the DC termination impedance of the receiver (I-V tables in IBIS

file) and doing frequency dependent simulations (e.g. return loss simulations) using the IBIS file is not very

accurate. It is recommended to use “GX3290_RX_Term.s2p” S-parameter file instead of the IBIS file in

order to do input return loss (IRL) simulations.

2.1.2 GX3290 Receiver AMI Model

The GX3290 Receiver model features adjustable trace equalization for PCB trace dielectric losses up to

half the maximum supported data rate, or 1.5GHz. The equalization setting can be adjusted by the

following model specific parameter:

EQ_Boost: The equalization has four different settings to compensate from 0 to 47 inches (119 cm) of FR4

trace at 3Gb/s. The boost at the 1.5GHz Nyquist frequency, and recommended trace length range, is shown

in Table 2-1.

Table 2-2: EQ_Boost parameter in the receiver AMI model.

EQ_Boost

Boost Applied @ 1.5GHz

Recommended Trace Length

0dB

0” to 6” (15cm)

3.5dB

6” (15cm) to 16” (40cm)

7.6dB

16” (40cm) to 35” (89cm)

PDS-060931 Rev.0 December 2014

12dB

35” (89cm) to 47” (119cm)

2.1.3 GX3290 Receiver Package Model

The GX3290 FCBGA package model is provided as a 4-Port S-parameter file (GX3290_RX_Pkg.s4p) in

standard touchstone format from 0 to 20 GHz with 2001 data points. This model has been developed for

one pair of differential input pins and the package model for the rest of input pins may be slightly different

from this model.

2.2 GX3290 Transmitter IBIS-AMI Model

The GX3290 Transmitter IBIS-AMI model consists of three parts: (1) the Analog Driver IBIS model, (2)

the Transmitter AMI model, and (3) the QFN package model. The block diagram in Figure 2-3 shows the

sequence of the signal flow and the individual parts of the model.

Figure 2-3: GX3290 Transmitter IBIS-AMI Model

2.2.1 GX3290 Analog Driver IBIS Model

The Analog Driver IBIS model receives processed signal information from the Transmitter AMI model and

applies the analog characteristics of the GX3290 Transmit driver. The model is based on a single-ended

non-inverting characterization of the GX3290 Receiver and the EDA platform develops a differential

model from complimentary copies of the single-ended model. Eight different sub-models have been

employed for different output swing settings. The appropriate sub-model has to be selected based on the

transmitter output swing and supply voltage. Table 2-3 summarizes the use of GX3290 receiver sub-

models.

Table 2-3: Transmitter sub-model selection based on the output swing and power supply.

Supply Voltage (V)

Output Swing (mVppd)

Sub-Model

1.2/1.8

200

Sdo_12_000

1.2/1.8

400

Sdo_12_001

1.2/1.8

800

Sdo_12_011

2.5

200

Sdo_25_000

2.5

400

Sdo_25_001

2.5

800

Sdo_25_011

2.5

1200

Sdo_25_110

PDS-060931 Rev.0 December 2014

2.5

1600

Sdo_25_111

Note that the IBIS model only contains the DC termination impedance of the receiver (I-V tables in IBIS

file) and doing frequency dependent simulations (e.g. return loss simulations) using the IBIS file is not very

accurate. It is recommended to use “GX3290_TX_Term.s2p” S-parameter file instead of the IBIS file in

order to do output return loss (ORL) simulations.

2.2.2 GX3290 Transmitter AMI Model

The GX3290 Transmitter AMI model consists of different de-emphasis settings which can be adjusted by a

model specific parameter. These parameters are described in the following. Note that these parameters are

the same as the registers in the datasheet. It is highly recommended that the user study the datasheet of

GX3290 and the register descriptions carefully before using the model.

1. Output_DeEmphasis: Selects the output de-emphasis level.

Table 2-4: Output_DeEmphasis in Transmitter AMI model.

Output_DeEmphasis

Level of De-emphasis

000

Off

100

12” (30 cm) nominal

101

24” (60 cm) nominal

110

36” (90 cm) nominal

111

48” (120 cm) nominal

2. Active_Signal_Invert: Inverts the polarity of the signal when it is set to 1.

2.2.3 GX3290 Transmitter Package Model

The GX3290 FCBGA package model is provided as a 4-Port S-parameter file (GX3290_TX_Pkg.s4p) in

standard touchstone format from 0 to 20GHz with 2001 data points. This model has been developed for one

pair of differential output pins and the package model for the rest of output pins may be slightly different

from this model.

Semtech GX3290 IBIS-AMI User guide

Brand: Semtech

Model: GX3290 IBIS-AMI

Type: User guide

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Semtech GX3290 IBIS-AMI User guide

Semtech GX3290 IBIS-AMI User guide

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