MAX9601EVKIT+ Maxim Integrated Products, MAX9601EVKIT+ Datasheet - Page 3

MAX9601EVKIT+

Manufacturer Part Number

MAX9601EVKIT+

Description

KIT EVALUATION FOR MAX9601

Manufacturer

Maxim Integrated Products

Datasheets

1.MAX9600EUP.pdf (12 pages)

2.MAX9601EVKIT.pdf (5 pages)

Specifications of MAX9601EVKIT+

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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The complementary latch-enable control permits track-

ing, track-hold, or sample-hold modes of operation.

The latch enables can be driven with PECL logic. See

Table 1 for the latch-enable truth table. By default, the

EV kit is configured to operate in compare mode. LEA

and LEB are connected to the VCCOA and VCCOB pads

through resistors R6 and R15 (LEA and LEB signals

need to be provided externally).

The EV kit’s default output termination network provides

the output with a Thevenin equivalent of 50I to VCCO_

- 2V, when connected to a 50I load to ground. Hence,

the outputs can be conveniently connected directly to

an oscilloscope’s 50I input. The termination network

provides a 4x output signal attenuation. If only one of

the serial-data outputs is connected to an oscilloscope,

ensure that the other is still properly terminated. Keep

in mind that the resistor networks at each output pro-

vide proper termination only when they are terminated

through 50I to ground.

The output can also be AC-coupled to the next stage.

While AC-coupling the output, remember that the IC

has an open-emitter output. Hence the output must

have a DC path provided with suitable external pull-

down resistors. Also, the resultant current sourced by

the output stage must not exceed the output current

capability of the part. For example, to AC-couple the QA

output to a 50I input oscilloscope, short resistor R19.

Replace resistor R2 with 125I and R27 with 187.5I. This

provides a DC Thevenin equivalent of 75I to VCCO - 2V.

Now replace resistor R1 with 49.9I resistor and populate

capacitor C1 with a suitable low-loss, high-frequency

capacitor. With good coupling, the AC load adds an

additional 8mA of output current only, since capacitor C1

blocks the DC component of the PECL output.

Table 1. Latch-Enable Truth Table

LATCH-ENABLE INPUT

LE_

_______________________________________________________________________________________

DC-Coupled Output to Oscilloscope

AC-Coupled Output to Oscilloscope

Compare mode (output follows

input state)

Latch mode (output latches to

last known output state)

Invalid condition (output is in

unknown state)

Output Termination

OPERATION

Latch Enable

MAX9601 Evaluation Kit

Alternative PECL output termination methods can be

used for different logic interfaces as long as they pro-

vide a DC Thevenin equivalent of 50I to VCC - 2V. For

example, to interface QA with a PECL or high-impedance

input, short resistors R1 and R19, and replace R27 with

a 124I resistor. To interface QA with a PECL input test

equipment, which is internally terminated with 50I to

VCCO_ - 2V, take the following steps:

The EV kit uses a two-layer board for simplicity. However,

special layout precautions have been taken due to the

large gain-bandwidth characteristics of the MAX9601.

The 0.01FF power-supply decoupling capacitors are

mounted as close as possible to the power-supply input

pins. The inductance of the return path is reduced by

flooding the ground plane with multiple vias. Multiple

ground vias are also present besides the decoupling

capacitors and signal traces to shorten the ground

return path and maximize isolation. The lead lengths

on the inputs and outputs are minimized to avoid

unwanted parasitic feedback around the comparators.

Microstrip layout and terminations are used at both the

inputs, as well as the outputs, to reduce signal reflec-

tions. Layer 2 is a continuous ground plane with no

signal or power traces. Impedance discontinuities have

been minimized by routing all the signal traces on the

top layer only, with no interconnecting vias or sharp cor-

ners. Edge-mount SMA connectors are used to reduce

the capacitive discontinuity and maximize frequency

response. The symmetric layout also minimizes the skew

due to the traces.

Note that a test setup optimized for high-speed mea-

surement is essential to observe the true performance of

the MAX9601 device. Use matched SMA cables for the

differential inputs and outputs. Also, account for the time

delay and skew of the test setup. For accurate measure-

ment of the device’s rise and fall times, an oscilloscope

with a bandwidth several times larger than the maximum

signal frequency must be used.

Remove resistors R2 and R27.

Short resistors R1 and R19.

Place a bias-T in series between the MAX9601 and

the test equipment. Connect the bias-T’s RF and DC

terminals to the QA output and the RF terminal to

the test equipment’s PECL input. Then connect the

DC terminal to a VCCO_ - 2V termination voltage

through a 50I resistor.

Alternative PECL Output Termination

Test Setup

Layout

MAX9601EVKIT+ Maxim Integrated Products, MAX9601EVKIT+ Datasheet - Page 3

MAX9601EVKIT+

Specifications of MAX9601EVKIT+

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