Tektronix Tektronix TTR506A Quickstart

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Vector Network Analyzer
Fundamentals

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POSTER

Vector Network Analyzer Fundamentals

Types of Measurement Error

WARNING: To reduce errors that affect measurement results, it is important to calibrate a VNA setup
regularly. Calibration reduces the impact of systematic and drift errors.

SYSTEMATIC ERROR RANDOM ERROR DRIFT ERROR

• Imperfections in the test
equipment or in the test setup

• Typically predictable

• Can be easily factored out by
a user calibration

• Examples that occur across
the frequency range:

- Output power variations

- Ripples in the VNA
receiver’s frequency
response

- Power loss of RF cables that
connect the DUT to the VNA

• Error caused by noise emitted
from the test equipment or test
setup that varies with time

• Determines the degree of
accuracy that can be achieved
in your measurement

• Cannot be factored out by a
user calibration

• Examples include:

- Trace noise

• Measurement drift and
variances that occur over time
in test equipment and test
setup after a user calibration

• The amount that the test setup
drifts over time determines
how often your test setup
needs to be recalibrated

• Examples include:

- Temperature changes

- Humidity changes

- Mechanical movement of

the setup

Basic VNA Operation

A VNA contains both a source, used to
generate a known stimulus signal, and a set
of receivers, used to determine changes to
this stimulus caused by the device-under­test or DUT. This illustration highlights the
basic operation of a VNA. For the sake of
simplicity, it shows the source coming from
Port 1, but most VNAs today are multipath
instruments and can provide the stimulus
signal to either port.

For simplicity, a single source is shown, but most VNAs today are multipath instruments and can
provide the stimulus signal to either port.

S-Parameter Basics

S-Parameter Definition: Scattering parameters or S-parameters describe the electrical properties and
performance of RF electrical components or networks of components when undergoing various steady
state electrical signal stimuli. They are unitless complex numbers, having both magnitude and phase, and
are related to familiar measurements such as gain, loss, and reflection coefficient.

Smith Chart 101

The Smith chart is a very useful tool used to determine complex impedances and admittances of RF
circuits. Most network analyzers can automatically display the Smith chart, plot measured data on it, and
provide adjustable markers to show the calculated impedance.

Impedance (Z = R+jX)

Toward

Generator

(Away From Load)

Im (z) = 0

Z = 0

(Short)

Away From

Generator

(Toward Load)

Impedance Smith Chart

1. The circles touching the right corner are
constant-resistance circles.

Z = 1

Impedance

Matched

I

m

(

z

)

m

I

=

1

1

-

=

)

z

(

=

)

1

z

(

e

R

2

=

)

z

(

e

R

Inductive

(+jX)

Z = ∞

(Open)

Capacitive

(-jX)

Toward

Generator

(Away From Load)

Y = ∞

(Short)

Away From

Generator

(Toward Load)

Admittance Smith Chart

1. The circles in the Smith chart that touch the
left corner are constant-conductance circles.

Admittance (Y = G+jB)

I

m

(

Y

)

1

=

)

Y

(

e

R

Y

(

e

)

R

=

2

=

-

1

Im (Y) = 0

Y = 1

Admittance

Matched

I

m

(

Y

)

=

1

Inductive

Capacitive

(-jB)

Y = 0

(Open)

(+jB)

Understanding VNA Calibration

Factory
Calibration

• Covers up to the
Port 1 and Port 2
connectors

VNA

Port 1 Port 2

User
Calibration

• Factors out the
effects of cables,
adaptors, and

2. The curves stretching from the right corner to
the outer edges of the impedance Smith chart
are constant-reactance curves.

3. The center of the circle is the Zo point. In
most cases, Zo = 50 ohms. This is also the
20-millisiemens (mS) point.

Common S-Parameter Names

2. The curves stretching from the left corner
of the Smith chart to the outer edges of
the admittance Smith chart are constant­susceptance curves.

• Ensures output
signals meet
specs and input
signals will be
represented
accurately

DUT

User Calibration

Reference Plane

most things used
in the connection
of the DUT

• Allows for exact
measurement
of the DUT
performance
alone

Benchtop performance,

Calibration Methods

For more information on S-parameters go to tek.com/VNAprimer

Key VNA Parameters

at a surprising price.

The TTR500 Series Vector Network Analyzer
rivals the leading benchtop competition,
at 40% lower cost and one-seventh the size
and weight! It has:

• 100 kHz up to 6 GHz
frequency range

• >122 dB dynamic range

• <0.008 dBrms trace noise

• -50 to +7 dBm output power

03/17 EA 2D-61077-0

Frequency Range

Consider not only your

immediate needs but also

potential future needs.

Dynamic Range

Make sure DUT noise

floor is at least 10 dB

above VNA spec.

Trace Noise

Random noise generated

by VNA that may affect

measurement accuracy.

Measurement Speed

Critical for high volume

manufacturing, less so for

most other applications.

• Bias Tee: 0 to ± 24 V
and 0 to 200 mA

All, backed by Tektronix legendary
service, support and quality.