NB7L216MNEVB Datasheet NB7L216MNEVB | P1-P3

February, 2012 − Rev. 1

1 Publication Order Number:

EVBUM2085/D

NB7L216MNEVB

NB7L216 Evaluation Board

User's Manual

Description

This document describes the NB7L216 evaluation board

and the appropriate lab test setups. It should be used in

conjunction with the NB7L216 data sheet which contains full

technical details on the device specifications and operation.

The evaluation board is designed to facilitate a quick

evaluation of the NB7L216 GigaCommt High Gain

Differential Receiver/Driver.

Board Lay−up

The evaluation board is implemented in two layers and

provides a high bandwidth 50 W controlled impedance

environment for higher performance. First layer or primary

trace layer is 5 mils thick Rogers RO6002 material, which

is engineered to have equal electrical length on all signal

traces from NB7L216 device to the sense output. The second

layer is 32 mils thick copper ground plane. For standard lab

setup and test, a split (dual) power supply is required

enabling the 50 ohm impedance in the scope to be used as

termination of the ECL signals (V

= V

– 2.0 V, in split

power supply setup, V

is the system ground).

What measurements can you expect to make?

With this evaluation board, the following measurements

could be performed in single−ended

(1)

or differential modes

of operation:

• Jitter

• Output Skew

• Gain/Return Loss

• Eye Pattern Generation

• Frequency Performance

• Output Rise and Fall Time

• V

CMR

(Common Mode Range)

1. Single−ended measurements can only be made at

− V

= 3.3 V using this board setup.

Figure 1. NB7L216 Evaluation Board

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EVAL BOARD USER’S MANUAL

NB7L216MNEVB

http://onsemi.com

SETUP FOR TIME DOMAIN MEASUREMENTS

Table 1. BASIC EQUIPMENT

Description Example Equipment (Note 1) Qty.

Power Supply with 4 outputs HP6624A 1

Oscilloscope TDS8000 with 80E01 Sampling Head (Note 2) 1

Differential Signal Generator HP 8133A, Advantest D3186 1

Matched High Speed Cables with SMA Connectors Storm, Semflex 4

Power Supply Cables with Clips 3/4

1. Equipment used to generate example measurements.

2. 50 GHz sampling head used (for effective rise, fall and jitter performance measurement)

Setup

Step 1: Connect Power

1a: Three power levels must be provided to the board for

, V

, and GND via the surface mount clips. Using the

split power supply mode, GND = V

= V

– 2.0 V.

Table 2. NB7L216 POWER SUPPLY CONNECTIONS

3.3 V Setup 2.5 V Setup

= 2.0 V V

= 2.0 V

= GND V

= GND

= −1.3 V V

= −0.5 V

Step 2: Connect Inputs

For Differential Mode (3.3 V and 2.5 V operation)

2a: Connect the differential output of the generator to the

differential input of the device (D and D

For Single−Ended Mode (3.3 V operation only)

2a: Connect the AC coupled single−ended output

generator to input.

NOTE: Device may oscillate when the input is not

driven. For best results, unconnected input

should be terminated to V

through 50 W

resistor.

OUT

TRIGGER

Channel 1 (80E01)

TRIGGER

Amplitude = 500 mV

Offset = 660 mV

Advantest D3186

Signal Generator

(12 GHz)

= 2.0 V

Tektronix TDS8000

Digital Oscilloscope

= −1.3 V (3.3 V op)

= −0.5 V (2.5 V op)

= 0 V

GND

= 0 V

GND

Figure 2. NB7L216 Board Setup − Time Domain (Differential Mode)

NOTE: All differential cable pairs must be matched.

Channel 2 (80E01)

NB7L216MNEVB

http://onsemi.com

Setup (continued)

Step 3: Setup Input Signals

3a: Set the signal generator amplitude to 500 mV.

NOTE: The signal generator amplitude can vary from

75 mV to 900 mV to produce a 400 mV DUT

output.

3b: Set the signal generator offset to 660 mV (the center of

a nominal RSECL output).

NOTE: The V

CMR

(Voltage Common Mode Range)

allows the signal generator offset to vary as long

as crosspoint is within the V

CMR

range. Refer to

the device data sheet for further information.

3c: Set the generator output for a PRBS data signal, or for a

square wave clock signal with a 50% duty cycle.

Step 4: Connect Output Signals

4a: Connect the outputs of the device (Q, Q) to the

oscilloscope. The oscilloscope sampling head must have

internal 50 W termination to ground.

NOTE: Where a single output is being used, the

unconnected output for the pair must be

terminated to V

through a 50 W resistor for

best operation. Unused pairs may be left

unconnected. Since V

= 0 V, a standard 50 W

SMA termination is recommended.

OUT

TRIGGER

Channel 1 (80E01)

TRIGGER

Amplitude = 500 mV

Offset = 660 mV

Advantest D3186

Signal Generator

(12 GHz)

Tektronix TDS8000

Digital Oscilloscope

= −1.3 V (3.3 V op)

GND

= 0 V

Channel 2 (80E01)

Figure 3. NB7L216 Board Setup − Time Domain (Single−Ended Mode)

AC Coupling

= 2.0 V

= 0 V

GND

NOTE: All differential cable pairs must be

matched.

SETUP FOR FREQUENCY DOMAIN MEASUREMENTS

Table 3. BASIC EQUIPMENT

Description Example Equipment (Note 3) Qty.

Power Supply with 4 outputs HP 6624A 1

Vector Network Analyzer (VNA) R&S ZVK (10 MHz to 40 GHz) 1

180° Hybrid Coupler Krytar Model #4010180 1

Bias Tee with 50 W Resistor Termination

Picosecond Model #5542−219 1

Matched High Speed Cables with SMA Connectors Storm, Semflex 3

Power Supply Cables with Clips 3/4

3. Equipment used to generate example measurements within this document.

P1-P3 P4-P6 P7-P9

NB7L216MNEVB

Mfr. #:

Buy NB7L216MNEVB

Manufacturer:

ON Semiconductor

Description:

Other Development Tools NB7L216 Eval Board 2.5V/3.3V 12Gb/s

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NB7L216MNEVB