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R&S®FSV/A3000 I/Q Analyzer and I/Q Input Interfaces

User Manual

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1178853602

User Manual

Version 01

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This manual applies to the following R&S®FSV3000 and R&S®FSVA3000 models with firmware version

1.10 and higher:

●

R&S®FSV3004 (1330.5000K04)

●

R&S®FSV3007 (1330.5000K07)

●

R&S®FSV3013 (1330.5000K13)

●

R&S®FSV3030 (1330.5000K30)

●

R&S®FSV3044 (1330.5000K43)

●

R&S®FSVA3004 (1330.5000K05)

●

R&S®FSVA3007 (1330.5000K08)

●

R&S®FSVA3013 (1330.5000K14)

●

R&S®FSVA3030 (1330.5000K31)

●

R&S®FSVA3044 (1330.5000K44)

In addition to the base unit, the following options are described:

●

R&S®FSV3-B4, OCXO (1330.3794.02)

●

R&S®FSV3-B5, Additional Interfaces (1330.3365.02/1330.3407.02)

●

R&S®FSV3-B10, external generator control (1330.3859.02)

●

R&S®FSV3-B13, high-pass filter (1313.0761.02)

●

R&S®FSV3-B24, preamplifier (1330.4049.XX)

●

R&S®FSV3-B25, electronic attenuator (1330.4078.02)

●

R&S®FSV3-B40, 40 MHz analysis bandwidth extension (1330.4103.02)

●

R&S®FSV3-B200, 200 MHz analysis bandwidth extenstion (1330.4132.02)

●

R&S®FSV3-B400, 400 MHz analysis bandwidth extenstion (1330.7154.02) / R&S®FSV3-U400 (1330.7183.02)

© 2019 Rohde & Schwarz GmbH & Co. KG Mühldorfstr. 15, 81671 München, Germany Phone: +49 89 41 29 - 0 Fax: +49 89 41 29 12 164 Email: info@rohde-schwarz.com Internet: www.rohde-schwarz.com Subject to change – Data without tolerance limits is not binding. R&S® is a registered trademark of Rohde & Schwarz GmbH & Co. KG. Trade names are trademarks of the owners.

1178.8536.02 | Version 01 | R&S®FSV/A3000 I/Q Analyzer

The following abbreviations are used throughout this manual: R&S®FSV/A3000 is abbreviated as R&S FSV/A3000 and refers to both the R&S FSV3000 and the R&S FSVA3000. Products of the R&S®SMW family, e.g. R&S®SMW200A, are abbreviated as R&S SMW.

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R&S®FSV/A3000 I/Q Analyzer

1 Preface.................................................................................................... 5

1.1 Documentation Overview............................................................................................. 5

1.2 About this Manual......................................................................................................... 7

1.3 Conventions Used in the Documentation...................................................................8

2 Welcome to the I/Q Analyzer Application............................................ 9

2.1 Starting the I/Q Analyzer Application..........................................................................9

2.2 Understanding the Display Information....................................................................10

3 Measurement and Result Displays.....................................................13

4 Basics on I/Q Data Acquisition and Processing............................... 17

4.1 Processing Analog I/Q Data from RF Input.............................................................. 17

Contents

4.2 Using Probes............................................................................................................... 21

4.3 Basics on External Generator Control...................................................................... 24

4.4 Basics on Input from I/Q Data Files...........................................................................35

4.5 IF and Video Signal Output........................................................................................ 36

4.6 Receiving and Providing Trigger Signals................................................................. 36

4.7 I/Q Data Import and Export.........................................................................................37

4.8 Basics on FFT..............................................................................................................38

5 Configuration........................................................................................45

5.1 Configuration Overview..............................................................................................45

5.2 Import/Export Functions............................................................................................ 47

5.3 Data Input and Output Settings................................................................................. 50

5.4 Amplitude.....................................................................................................................65

5.5 Frequency Settings.....................................................................................................70

5.6 Trigger Settings...........................................................................................................71

5.7 Data Acquisition and Bandwidth Settings................................................................77

5.8 Display Configuration.................................................................................................85

5.9 Adjusting Settings Automatically..............................................................................85

6 Analysis................................................................................................ 89

6.1 Trace Settings..............................................................................................................89

6.2 Spectrogram Settings.................................................................................................93

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6.3 Trace / Data Export Configuration.............................................................................97

6.4 Marker Usage.............................................................................................................100

7 How to Work with I/Q Data................................................................ 125

7.1 How to Perform Measurements in the I/Q Analyzer Application.......................... 125

7.2 How to Export and Import I/Q Data..........................................................................125

8 Remote Commands to Perform Measurements with I/Q Data....... 128

8.1 Introduction............................................................................................................... 128

8.2 Common Suffixes......................................................................................................133

8.3 Activating I/Q Analyzer Measurements...................................................................134

8.4 Configuring I/Q Analyzer Measurements................................................................139

8.5 Configuring the Result Display................................................................................202

8.6 Capturing Data and Performing Sweeps................................................................ 210

Contents

8.7 I/Q Analysis................................................................................................................216

8.8 Retrieving Results.....................................................................................................264

8.9 Importing and Exporting I/Q Data and Results...................................................... 275

8.10 Programming Examples........................................................................................... 276

8.11 Deprecated Commands............................................................................................279

Annex.................................................................................................. 281

A Formats for Returned Values: ASCII Format and Binary Format.. 283

B Reference: Format Description for I/Q Data Files........................... 284

C I/Q Data File Format (iq-tar)...............................................................286

C.1 I/Q Parameter XML File Specification......................................................................287

C.2 I/Q Data Binary File................................................................................................... 290

List of Commands (I/Q Analyzer)......................................................292

Index....................................................................................................300

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R&S®FSV/A3000 I/Q Analyzer

1 Preface

This chapter provides safety-related information, an overview of the user documentation and the conventions used in the documentation.

1.1 Documentation Overview

This section provides an overview of the R&S FSV/A user documentation. Unless specified otherwise, you find the documents on the R&S FSV/A product page at:

www.rohde-schwarz.com/manual/FSV3000

1.1.1 Getting Started Manual

Introduces the R&S FSV/A and describes how to set up and start working with the product. Includes basic operations, typical measurement examples, and general information, e.g. safety instructions, etc.

Preface

Documentation Overview

A printed version is delivered with the instrument. A PDF version is available for download on the Internet.

1.1.2 User Manuals and Help

Separate user manuals are provided for the base unit and the firmware applications:

●

Base unit manual Contains the description of all instrument modes and functions. It also provides an introduction to remote control, a complete description of the remote control commands with programming examples, and information on maintenance, instrument interfaces and error messages. Includes the contents of the getting started manual.

●

Firmware application manual Contains the description of the specific functions of a firmware application, including remote control commands. Basic information on operating the R&S FSV/A is not included.

The contents of the user manuals are available as help in the R&S FSV/A. The help offers quick, context-sensitive access to the complete information for the base unit and the firmware applications.

All user manuals are also available for download or for immediate display on the Internet.

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R&S®FSV/A3000 I/Q Analyzer

1.1.3 Service Manual

Describes the performance test for checking the rated specifications, module replacement and repair, firmware update, troubleshooting and fault elimination, and contains mechanical drawings and spare part lists.

The service manual is available for registered users on the global Rohde & Schwarz information system (GLORIS):

https://gloris.rohde-schwarz.com

1.1.4 Instrument Security Procedures

Deals with security issues when working with the R&S FSV/A in secure areas. It is available for download on the Internet.

1.1.5 Basic Safety Instructions

Preface

Documentation Overview

Contains safety instructions, operating conditions and further important information. The printed document is delivered with the instrument.

1.1.6 Data Sheets and Brochures

The data sheet contains the technical specifications of the R&S FSV/A. It also lists the firmware applications and their order numbers, and optional accessories.

The brochure provides an overview of the instrument and deals with the specific characteristics.

See www.rohde-schwarz.com/brochure-datasheet/FSV3000

1.1.7 Release Notes and Open Source Acknowledgment (OSA)

The release notes list new features, improvements and known issues of the current firmware version, and describe the firmware installation.

The open source acknowledgment document provides verbatim license texts of the used open source software.

See www.rohde-schwarz.com/firmware/FSV3000

1.1.8 Application Notes, Application Cards, White Papers, etc.

These documents deal with special applications or background information on particular topics.

See www.rohde-schwarz.com/application/FSV3000

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R&S®FSV/A3000 I/Q Analyzer

1.2 About this Manual

This R&S FSV/A I/Q Analyzer User Manual provides all the information specific to the application and processing I/Q data. All general instrument functions and settings

common to all applications are described in the main R&S FSV/A User Manual.

The main focus in this manual is on the measurement results and the tasks required to obtain them. The following topics are included:

●

Welcome to the I/Q Analyzer application

Introduction to and getting familiar with the application

●

Typical Applications for the I/Q Analyzer and optional input interfaces

Example measurement scenarios for I/Q data import and analysis

●

Measurements and Result Displays

Details on supported measurements and their result types

●

Basics on I/Q Data Acquisition

Background information on basic terms and principles in the context of the I/Q Analyzer application as well as processing I/Q data in general

●

Configuration and Analysis

A concise description of all functions and settings available to import, capture and analyze I/Q data in the I/Q Analyzer, with or without optional interfaces, with their corresponding remote control command

●

How to Work with I/Q Data

The basic procedure to perform an I/Q Analyzer measurement with step-by-step instructions

●

Optimizing and Troubleshooting the Measurement

Hints and tips on how to handle errors and optimize the test setup

●

Remote Commands to perform Measurements with I/Q Data

Remote commands required to configure and perform I/Q Analyzer measurements or process digital I/Q data in a remote environment, sorted by tasks; (Commands required to set up the environment or to perform common tasks on the instrument are provided in the main R&S FSV/A User Manual.) Programming examples demonstrate the use of many commands and can usually be executed directly for test purposes.

●

Annex

Reference material, e.g. I/Q file formats and a detailed description of the LVDS connector

●

List of remote commands

Alphabetical list of all remote commands described in the manual

●

Index

Preface

About this Manual

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1.3 Conventions Used in the Documentation

1.3.1 Typographical Conventions

The following text markers are used throughout this documentation:

Convention Description

Preface

Conventions Used in the Documentation

"Graphical user interface elements"

[Keys] Key and knob names are enclosed by square brackets.

Filenames, commands, program code

Input Input to be entered by the user is displayed in italics.

Links Links that you can click are displayed in blue font.

"References" References to other parts of the documentation are enclosed by quota-

All names of graphical user interface elements on the screen, such as dialog boxes, menus, options, buttons, and softkeys are enclosed by quotation marks.

Filenames, commands, coding samples and screen output are distinguished by their font.

tion marks.

1.3.2 Conventions for Procedure Descriptions

When operating the instrument, several alternative methods may be available to perform the same task. In this case, the procedure using the touchscreen is described. Any elements that can be activated by touching can also be clicked using an additionally connected mouse. The alternative procedure using the keys on the instrument or the on-screen keyboard is only described if it deviates from the standard operating procedures.

The term "select" may refer to any of the described methods, i.e. using a finger on the touchscreen, a mouse pointer in the display, or a key on the instrument or on a keyboard.

1.3.3 Notes on Screenshots

When describing the functions of the product, we use sample screenshots. These screenshots are meant to illustrate as many as possible of the provided functions and possible interdependencies between parameters. The shown values may not represent realistic usage scenarios.

The screenshots usually show a fully equipped product, that is: with all options installed. Thus, some functions shown in the screenshots may not be available in your particular product configuration.

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R&S®FSV/A3000 I/Q Analyzer

2 Welcome to the I/Q Analyzer Application

The R&S FSV3 I/Q Analyzer is a firmware application that adds functionality to perform I/Q data acquisition and analysis to the R&S FSV/A.

The R&S FSV3 I/Q Analyzer features:

●

Acquisition of analog I/Q data

●

Import of stored I/Q data from other applications

●

Spectrum, magnitude, I/Q vector and separate I and Q component analysis of any I/Q data on the instrument

●

Export of I/Q data to other applications

This user manual contains a description of the functionality that the application provides, including remote control operation.

All functions not discussed in this manual are the same as in the base unit and are described in the R&S FSV/A User Manual. The latest version is available for download at the product homepage http://www.rohde-schwarz.com/product/FSVA3000.

Welcome to the I/Q Analyzer Application

Starting the I/Q Analyzer Application

Additional information

Several application notes discussing I/Q analysis are available from the Rohde & Schwarz website:

1EF85: Converting R&S I/Q data files

1EF92: Wideband Signal Analysis

1MA257: Wideband mm-Wave Signal Generation and Analysis

1EF84: Differential measurements with Spectrum Analyzers and Probes

Installation

The R&S FSV3 I/Q Analyzer application is part of the standard base unit and requires no further installation.

2.1 Starting the I/Q Analyzer Application

The I/Q Analyzer is an application on the R&S FSV/A.

To activate the I/Q Analyzer application

1. Select the [MODE] key. A dialog box opens that contains all applications currently available on your

R&S FSV/A.

2. Select the "I/Q Analyzer" item.

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R&S®FSV/A3000 I/Q Analyzer

The R&S FSV/A opens a new channel for the I/Q Analyzer application.

The measurement is started immediately with the default settings.

It can be configured in the I/Q Analyzer "Overview" dialog box, which is displayed when you select the "Overview" softkey from any menu (see Chapter 5.1, "Configura-

tion Overview", on page 45).

Multiple Channels and Sequencer Function

When you activate an application, a new channel is created which determines the measurement settings for that application (channel). The same application can be activated with different measurement settings by creating several channels for the same application.

The number of channels that can be configured at the same time depends on the available memory on the instrument.

Welcome to the I/Q Analyzer Application

Understanding the Display Information

Only one measurement can be performed at any time, namely the one in the currently active channel. However, in order to perform the configured measurements consecutively, a Sequencer function is provided.

If activated, the measurements configured in the currently defined channels are performed one after the other in the order of the tabs. The currently active measurement is indicated by a

The result displays of the individual channels are updated in the tabs (as well as the "MultiView" ) as the measurements are performed. Sequential operation itself is independent of the currently displayed tab.

For details on the Sequencer function see the R&S FSV/A User Manual.

symbol in the tab label.

2.2 Understanding the Display Information

The following figure shows a measurement diagram during I/Q Analyzer operation. All different information areas are labeled. They are explained in more detail in the following sections.

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R&S®FSV/A3000 I/Q Analyzer

2 3

Welcome to the I/Q Analyzer Application

Understanding the Display Information

Figure 2-1: Screen elements in the I/Q Analyzer application

1 = Channel bar for firmware and measurement settings 2+3 = Window title bar with diagram-specific (trace) information 4 = Diagram area with marker information 5 = Diagram footer with diagram-specific information, depending on result display 6 = Instrument status bar with error messages and date/time display

Channel bar information

In the I/Q Analyzer application, the R&S FSV/A shows the following settings:

Table 2-1: Information displayed in the channel bar for the I/Q Analyzer application

Ref Level Reference level

(m.+el.)Att (Mechanical and electronic) RF attenuation

Ref Offset Reference level offset

Freq Center frequency

Meas Time Measurement time

Rec Length Defined record length (number of samples to capture)

SRate Defined sample rate for data acquisition

RBW (Spectrum evaluation only) Resolution bandwidth calculated from the

sample rate and record length

In addition, the channel bar also displays information on instrument settings that affect the measurement results even though this is not immediately apparent from the display of the measured values (e.g. transducer or trigger settings). This information is displayed only when applicable for the current measurement. For details see the R&S FSV/A Getting Started manual.

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Window title bar information

For each diagram, the header provides the following information:

Figure 2-2: Window title bar information in the I/Q Analyzer application

1 = Window number 2 = Window type 3 = Trace color 4 = Trace number 5 = Detector 6 = Trace mode

Diagram footer information

The information in the diagram footer (beneath the diagram) depends on the evaluation:

Welcome to the I/Q Analyzer Application

Understanding the Display Information

●

Center frequency

●

Number of sweep points

●

Range per division (x-axis)

●

Span (Spectrum)

Status bar information

Global instrument settings, the instrument status and any irregularities are indicated in the status bar beneath the diagram.

Furthermore, the progress of the current operation is displayed in the status bar.

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R&S®FSV/A3000 I/Q Analyzer

3 Measurement and Result Displays

Access: "Overview" > "Display Config"

Or: [MEAS] > "Display Config"

The I/Q Analyzer can capture I/Q data. The I/Q data that was captured by or imported to the R&S FSV/A can then be evaluated in various different result displays. Select the result displays using the SmartGrid functions.

Up to 6 evaluations can be displayed in the I/Q Analyzer at any time, including several graphical diagrams, marker tables or peak lists.

For details on working with the SmartGrid see the R&S FSV/A Getting Started manual.

Measurements in the time and frequency domain

The time and frequency domain measurements and the available results are described in detail in the R&S FSV/A User Manual.

Measurement and Result Displays

Result displays for I/Q data:

Magnitude .................................................................................................................... 13

Spectrum ......................................................................................................................13

I/Q-Vector .....................................................................................................................14

Real/Imag (I/Q) .............................................................................................................15

Marker Table ................................................................................................................ 15

Marker Peak List .......................................................................................................... 15

Magnitude

Shows the level values in time domain.

Remote command: LAY:ADD:WIND? '1',RIGH,MAGN, see LAYout:ADD[:WINDow]? on page 204 Results:

TRACe<n>[:DATA] on page 269

Spectrum

Displays the frequency spectrum of the captured I/Q samples.

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Remote command: LAY:ADD:WIND? '1',RIGH,FREQ, see LAYout:ADD[:WINDow]? on page 204 Results:

TRACe<n>[:DATA] on page 269

Measurement and Result Displays

I/Q-Vector

Displays the captured samples in an I/Q-plot. The samples are connected by a line.

Note: For the I/Q vector result display, the number of I/Q samples to record ( "Record Length" ) must be identical to the number of trace points to be displayed ("Sweep Points"; for I/Q Analyzer: 10001). For record lengths outside the valid range of sweep points the diagram does not show valid results.

Remote command: LAY:ADD:WIND? '1',RIGH,VECT, see LAYout:ADD[:WINDow]? on page 204 Results:

TRACe<n>[:DATA] on page 269

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Real/Imag (I/Q)

Displays the I and Q values in separate diagrams.

Measurement and Result Displays

Remote command: LAY:ADD:WIND? '1',RIGH,RIM, see LAYout:ADD[:WINDow]? on page 204 Results:

TRACe<n>[:DATA] on page 269

Marker Table

Displays a table with the current marker values for the active markers.

Tip: To navigate within long marker tables, simply scroll through the entries with your finger on the touchscreen.

Remote command: LAY:ADD? '1',RIGH, MTAB, see LAYout:ADD[:WINDow]? on page 204 Results:

CALCulate<n>:MARKer<m>:X on page 235 CALCulate<n>:MARKer<m>:Y on page 274

Marker Peak List

The marker peak list determines the frequencies and levels of peaks in the spectrum or time domain. How many peaks are displayed can be defined, as well as the sort order. In addition, the detected peaks can be indicated in the diagram. The peak list can also be exported to a file for analysis in an external application.

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Tip: To navigate within long marker peak lists, simply scroll through the entries with

your finger on the touchscreen. Remote command:

LAY:ADD? '1',RIGH, PEAK, see LAYout:ADD[:WINDow]? on page 204 Results:

CALCulate<n>:MARKer<m>:X on page 235 CALCulate<n>:MARKer<m>:Y on page 274

Measurement and Result Displays

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R&S®FSV/A3000 I/Q Analyzer

4 Basics on I/Q Data Acquisition and Pro-

cessing

Some background knowledge on basic terms and principles used when describing I/Q data acquisition on the R&S FSV/A in general, and in the I/Q Analyzer application in particular, is provided here for a better understanding of the required configuration settings.

The I/Q Analyzer provides various possibilities to acquire the I/Q data to be analyzed:

●

Capturing analog I/Q data from the "RF Input" connector

●

Importing I/Q data from a file

Background information for all these scenarios and more is provided in the following sections.

● Processing Analog I/Q Data from RF Input.............................................................17

● Using Probes...........................................................................................................21

● Basics on External Generator Control.....................................................................24

● Basics on Input from I/Q Data Files........................................................................ 35

● IF and Video Signal Output.....................................................................................36

● Receiving and Providing Trigger Signals................................................................ 36

● I/Q Data Import and Export..................................................................................... 37

● Basics on FFT.........................................................................................................38

Basics on I/Q Data Acquisition and Processing

Processing Analog I/Q Data from RF Input

4.1 Processing Analog I/Q Data from RF Input

Complex baseband data

In the telephone systems of the past, baseband data was transmitted unchanged as an analog signal. In modern phone systems and in radio communication, however, the baseband data is modulated on a carrier frequency, which is then transmitted. The receiver must demodulate the data based on the carrier frequency. When using modern modulation methods (e.g. QPSK, QAM etc.), the baseband signal becomes complex. Complex data (or: I/Q data) consists of an imaginary (I) and a real (Q) component.

Sweep vs sampling

The standard Spectrum application on the R&S FSV/A performs frequency sweeps on the input signal and measurements in the frequency and time domain. Other applications on the R&S FSV/A, such as the I/Q Analyzer, sample and process the individual I and Q components of the complex signal.

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R&S®FSV/A3000 I/Q Analyzer

I/Q Analyzer - processing complex data from RF input

The I/Q Analyzer is a standard application used to capture and analyze I/Q data on the R&S FSV/A. By default, it assumes the I/Q data is modulated on a carrier frequency and input via the "RF Input" connector on the R&S FSV/A.

The A/D converter samples the IF signal at a rate of 200 MHz. The digital signal is down-converted to the complex baseband, lowpass-filtered, and the sample rate is reduced. The analog filter stages in the analyzer cause a frequency response which adds to the modulation errors. An equalizer filter before the resampler compensates for this frequency response. The continuously adjustable sample rates are realized using an optimal decimation filter and subsequent resampling on the set sample rate.

A dedicated memory (capture buffer) is available in the R&S FSV/A for a maximum of 400 Msamples (400*1000*1000) of complex samples (pairs of I and Q data). The number of complex samples to be captured can be defined (for restrictions refer to Chap-

ter 4.1.1, "Sample Rate and Maximum Usable I/Q Bandwidth for RF Input",

on page 18).

The block diagram in Figure 4-1 shows the analyzer hardware from the IF section to the processor.

Basics on I/Q Data Acquisition and Processing

Processing Analog I/Q Data from RF Input

Figure 4-1: Block diagram illustrating the R&S FSV/A signal processing for analog I/Q data (without

bandwidth extension options)

4.1.1 Sample Rate and Maximum Usable I/Q Bandwidth for RF Input

Definitions

●

Input sample rate (ISR): the sample rate of the useful data provided by the device connected to the input of the R&S FSV/A

●

(User, Output) Sample rate (SR): the user-defined sample rate (e.g. in the "Data Acquisition" dialog box in the "I/Q Analyzer" application) which is used as the basis for analysis or output

●

Usable I/Q (Analysis) bandwidth: the bandwidth range in which the signal remains undistorted in regard to amplitude characteristic and group delay; this range can be used for accurate analysis by the R&S FSV/A

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R&S®FSV/A3000 I/Q Analyzer

●

Record length: Number of I/Q samples to capture during the specified measurement time; calculated as the measurement time multiplied by the sample rate

For the I/Q data acquisition, digital decimation filters are used internally in the R&S FSV/A. The passband of these digital filters determines the maximum usable I/Q bandwidth. In consequence, signals within the usable I/Q bandwidth (passband) remain unchanged, while signals outside the usable I/Q bandwidth (passband) are suppressed. Usually, the suppressed signals are noise, artifacts, and the second IF side band. If frequencies of interest to you are also suppressed, try to increase the output sample rate, which increases the maximum usable I/Q bandwidth.

Bandwidth extension options

You can extend the maximum usable I/Q bandwidth provided by the R&S FSV/A in the basic installation by adding options. These options can either be included in the initial installation (B-options) or updated later (U-options). The maximum bandwidth provided by the individual option is indicated by its number, for example, B40 extends the bandwidth to 40 MHz.

Basics on I/Q Data Acquisition and Processing

Processing Analog I/Q Data from RF Input

As a rule, the usable I/Q bandwidth is proportional to the output sample rate. Yet, when the I/Q bandwidth reaches the bandwidth of the analog IF filter (at very high output sample rates), the curve breaks.

● Bandwidth Extension Options................................................................................. 19

● Relationship Between Sample Rate, Record Length and Usable I/Q Bandwidth... 19

● R&S FSV/A Without Additional Bandwidth Extension Options............................... 20

● R&S FSV/A with I/Q Bandwidth Extension Option B40 or U40...............................20

● R&S FSV/A with I/Q Bandwidth Extension Option B200 or U200...........................21

● R&S FSV/A with I/Q Bandwidth Extension Option B400 or U400...........................21

4.1.1.1 Bandwidth Extension Options

Max. usable I/Q BW Required B-option

40 MHz B40

200 MHz B200

400 MHz B400

4.1.1.2 Relationship Between Sample Rate, Record Length and Usable I/Q Bandwidth

Up to the maximum bandwidth, the following rule applies:

Usable I/Q bandwidth = 0.8 * Output sample rate

Regarding the record length, the following rule applies:

Record length = Measurement time * sample rate

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R&S®FSV/A3000 I/Q Analyzer

Maximum record length for RF input

The maximum record length, that is, the maximum number of samples that can be captured, is 100 MSamples (with option B114: 800 MSamples).

The Figure 4-2 shows the maximum usable I/Q bandwidths depending on the output sample rates.

Basics on I/Q Data Acquisition and Processing

Processing Analog I/Q Data from RF Input

Figure 4-2: Relationship between maximum usable I/Q bandwidth and output sample rate with and

without bandwidth extensions

4.1.1.3 R&S FSV/A Without Additional Bandwidth Extension Options

Sample rate: 100 Hz - 10 GHz

Maximum I/Q bandwidth: 10 MHz

Table 4-1: Maximum I/Q bandwidth

Sample rate Maximum I/Q bandwidth

100 Hz to 10 MHz Proportional up to maximum 10 MHz

10 MHz to 10 GHz 10 MHz

4.1.1.4 R&S FSV/A with I/Q Bandwidth Extension Option B40 or U40

Sample rate: 100 Hz - 10 GHz

Maximum bandwidth: 40 MHz

Sample rate Maximum I/Q bandwidth

100 Hz to 50 MHz Proportional up to maximum 40 MHz

50 MHz to 10 GHz 40 MHz

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4.1.1.5 R&S FSV/A with I/Q Bandwidth Extension Option B200 or U200

Sample rate: 100 Hz - 10 GHz

Maximum bandwidth: 200 MHz

Sample rate Maximum I/Q bandwidth

100 Hz to 250 MHz Proportional up to maximum 200 MHz

250 MHz to 10 GHz 200 MHz

4.1.1.6 R&S FSV/A with I/Q Bandwidth Extension Option B400 or U400

Sample rate: 100 Hz - 10 GHz

Maximum bandwidth: 400 MHz

Sample rate Maximum I/Q bandwidth

100 Hz to 500 MHz Proportional up to maximum 400 MHz

Basics on I/Q Data Acquisition and Processing

Using Probes

500 MHz to 10 GHz 400 MHz

4.2 Using Probes

Probes allow you to perform voltage measurements very flexibly and precisely on all sorts of devices to be tested, without interfering with the signal. The R&S FSV/A base unit and some (optional) applications support input from probes.

Probe connectors

Active probes

When using active probes from the R&S RT family, consider the following:

●

Active probes require operating power from the instrument and have a proprietary interface to the instrument.

●

The probe is automatically recognized by the instrument, no adjustment is required.

●

Connections should be as short as possible to keep the usable bandwidth high.

●

Observe the operating voltage range.

Microbutton action

You can define an action to be performed by the R&S FSV/A when the probe's microbutton (if available) is pressed. Currently, a single data acquisition via the probe can be performed simply by pressing the microbutton.

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4.2.1 RF Probes

Active modular probes can be connected to the RF Input connector on the R&S FSV/A using an R&S RT-ZA9 adapter. Thus, you can perform frequency sweeps on data from all active probes with a maximum bandwidth of up to 80 MHz, depending on the installed bandwidth extension options. The R&S RT-ZA9 provides an interface between the probe's BNC socket and the analyzer's N-socket. The USB connection provides the necessary supply voltages for the probe.

To connect an active probe to the RF Input

1. Connect the R&S RT-ZA9 adapter to the RF Input connector on the R&S FSV/A.

2. Connect the R&S RT-ZA9 adapter's USB cable to a USB connector on the R&S FSV/A.

3. Connect the probe to the adapter.

Basics on I/Q Data Acquisition and Processing

Using Probes

Probes are automatically detected when you plug them into the R&S FSV/A. The detected information on the probe is displayed in the "Probes" tab of the "Input" dialog box.

To determine whether the probe has been connected properly and recognized by the R&S FSV/A, use the [SENSe:]PROBe<pb>:SETup:STATe? remote control command.

Impedance and attenuation

The measured signal from the probe is attenuated internally by the probe's specific attenuation. For RF probes, the attenuation is compensated using a pre-defined "Probe on RF Input" transducer factor, which is automatically activated before the common RF data processing. The reference level is adjusted automatically.

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A fixed impedance of 50 Ω is used for all probes to convert voltage values to power levels.

4.2.1.1 MultiMode Function and Offset Compensation for Modular RF Probes

The R&S RT-ZM probe family features the MultiMode function which allows you to switch between single-ended, differential, and common mode measurements without reconnecting or resoldering the probe.

Four different input voltages can be measured with the MultiMode feature:

●

P-Mode: (pos.) Single-ended input voltage (Vp) Voltage between the positive input terminal and ground

●

N-Mode: (neg.) Single-ended input voltage (Vn) Voltage between the negative input terminal and ground

●

DM-Mode: Differential mode input voltage (Vdm) Voltage between the positive and negative input terminal

Basics on I/Q Data Acquisition and Processing

Using Probes

●

CM-Mode: Common mode input voltage (Vcm) Mean voltage between the positive and negative input terminal vs. ground

The R&S FSV/A supports all probe modes. The mode is configured in the Chap-

ter 5.3.1.3, "Probe Settings", on page 54.

Offset compensation

The R&S RT-ZM probes feature a comprehensive offset compensation function. The compensation of DC components directly at the probe tip even in front of the active probe amplifier is possible with an extremely wide compensation range of ±16 V (±24 V for P and N modes).

The offset compensation feature is available for every MultiMode setting:

MultiMode setting

DM-Mode Differential DC voltage ±16 V Probing single-ended signals, e.g. power

CM-Mode Common mode DC volt-

Offset compensation Offset compen-

sation range

±16 V Measurements of signals with high common

age

Application

rails with high DC component and small AC signal.

mode levels, e.g. current measurements with a shunt resistor.

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Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

MultiMode setting

P-Mode DC voltage at positive

N-Mode DC voltage at negative

Offset compensation Offset compen-

sation range

±24 V Measurement of single-ended AC signals

input terminal

±24 V Measurement of single ended AC signals

input terminal

Application

with high superimposed DC component at the positive input terminal.

Note: The maximum voltage difference between the positive and negative input terminals is 16 V.

with high superimposed DC component at the negative input terminal.

Note: The maximum voltage difference between the positive and negative input terminals is 16 V.

If the offset for DM-mode or CM-mode is changed, the offsets for the P-mode and Nmode are adapted accordingly, and vice versa.

4.3 Basics on External Generator Control

Some background knowledge on basic terms and principles used for external generator control is provided here for a better understanding of the required configuration settings.

External generator control is only available in the following applications.

●

Spectrum Analyzer

●

I/Q Analyzer

●

Analog Demodulation

●

Noise Figure Measurements

● External Generator Connections.............................................................................24

● Overview of Supported Generators.........................................................................27

● Generator Setup Files.............................................................................................28

● Calibration Mechanism............................................................................................29

● Normalization.......................................................................................................... 29

● Reference Trace, Reference Line and Reference Level.........................................31

● Coupling the Frequencies....................................................................................... 31

● Displayed Information and Errors............................................................................34

4.3.1 External Generator Connections

The external generator is controlled either via a LAN connection or via the EXT. GEN. CONTROL GPIB interface of the R&S FSV/A supplied with the option.

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For more information on configuring interfaces see the "Remote Control Interfaces and Protocols" section in the R&S FSV/A User Manual.

TTL synchronization

In addition, TTL synchronization can be used with some Rohde & Schwarz generators connected via GPIB. The TTL interface is included in the AUX control connector of the External Generator Control option.

Using the TTL interface allows for considerably higher measurement rates than pure GPIB control, because the frequency stepping of the R&S FSV/A is directly coupled with the frequency stepping of the generator. For details see Chapter 4.3.7, "Coupling

the Frequencies", on page 31.

In Figure 4-3, the connection for an R&S SMW is shown.

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

R&S SMW

rear panel

BNC Trigger

BNC Blank

R&S FSW rear panel

Figure 4-3: TTL connection for an R&S SMW generator

The external generator can be used to calibrate the data source by performing either transmission or reflection measurements.

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Transmission Measurement

This measurement yields the transmission characteristics of a two-port network. The external generator is used as a signal source. It is connected to the input connector of the DUT. The input of the R&S FSV/A is fed from the output of the DUT. A calibration can be carried out to compensate for the effects of the test setup (e.g. frequency response of connecting cables).

Figure 4-4: Test setup for transmission measurement

Reflection Measurement

Scalar reflection measurements can be carried out using a reflection-coefficient measurement bridge.

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Figure 4-5: Test setup for reflection measurement

Generated signal input

In order to use the functions of the external generator, an appropriate generator must be connected and configured correctly. In particular, the generator output must be connected to the RF input of the R&S FSV/A.

External reference frequency

In order to enhance measurement accuracy, a common reference frequency should be used for both the R&S FSV/A and the generator. If no independent 10 MHz reference frequency is available, it is recommended that you connect the reference output of the generator with the reference input of the R&S FSV/A and that you enable usage of the external reference on the R&S FSV/A via "SETUP" > "Reference" > "External Reference".

For more information on external references see the "Instrument Setup" section in the R&S FSV/A User Manual.

Connection errors

If no external generator is connected, if the connection address is not correct, or the generator is not ready for operation, an error message is displayed (e.g."Ext. Genera-

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tor TCPIP Handshake Error!", see Chapter 4.3.8, "Displayed Information and Errors", on page 34).

4.3.2 Overview of Supported Generators

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Generator

Model Driver file TTL sup-

type

SGS100A 6 GHz SGS100A6 -

port

Generator type Model Driver file TTL sup-

SMJ 3 GHz SMJ03 X

12 GHz SGS100A12 - 6 GHz SMJ06 X

SGT100A 3 GHz SGT100A3 - SML 1 GHz SML01 -

6 GHz SGT100A6 - 2 GHz SML02 -

SMA01A 3 GHz

SMA01A

3 GHz SML03 -

SMA100A 3 GHz SMA100A3 X SMP 2 GHz SMP02 X

6 GHz SMA100A6 X 3 GHz SMP03 X

SMB100A 1 GHz SMB100A1 X 4 GHz SMP04 X

12 GHz SMB100A12 X 22 GHz SMP22 X

2 GHz SMB100A2 X SMR 20 GHz SMR20 -

20 GHz SMB100A20 X 20 GHz

SMR20B11

3 GHz SMB100A3 X 27 GHz SMR27 X

40 GHz SMB100A40 X 27 GHz

SMR27B11

SMBV100A 3 GHz SMBV100A3 X 30 GHz SMR30 X

6 GHz SMBV100A6 X 30 GHz

SMR30B11

port

SMB100B 1 GHz SMB100B1 X 40 GHz SMR40 X

3 GHz SMB100B3 X 40 GHz

SMR40B11

6 GHz SMB100B6 X 50 GHz SMR50 X

SMBV100B 3 GHz SMBV100B3 X 50 GHz

SMR50B11

6 GHz SMBV100B6 X 60 GHz SMR60 X

SMC100A 1 GHz SMC100A1 - 60 GHz

3 GHz SMC100A3 -

SMT 2 GHz SMT02 -

SMR60B11

SME 2 GHz SME02 X 3 GHz SMT03 -

3 GHz SME03 X 6 GHz SMT06 -

6 GHz SME06 X

SMU 2 GHz SMU02 X

1) Requires firmware version V2.10.x or higher on the signal generator

2) Requires firmware version V1.10.x or higher on the signal generator

3) Requires the option SMR-B11 on the signal generator

4) Requires firmware version V3.20.200 or higher on the signal generator

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Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Generator type

SMF100A 43.5 GHz SMF100A X 2 GHz

SMF 22 GHz SMF22 X 3 GHz

SMG all SMG - 6 GHz

SMGL all SMGL - 6 GHz

SMGU all SMGU -

SMH all SMH -

SMHU

SMIQ 2 GHz SMIQ02 X 20 GHz SMW20

Model Driver file TTL sup-

port

22 GHz SMF22B2 X 3 GHz

43 GHz SMF43 X 4 GHz

43 GHz SMF43B2 X 4 GHz

2 GHz SMIQ02B X 40 GHz SMW40

2 GHz SMIQ02E -

3 GHz SMIQ03 X

SMHU - 6 GHz SMW06

Generator type Model Driver file TTL sup-

SMU02B31

SMU03

SMU03B31

SMU04

SMU04B31

SMU06

SMU06B31

SMV 3 GHz SMV03 -

SMW 3 GHz SMW03

SMX all SMX -

SMY 1 GHz SMY01 -

port

3 GHz SMIQ03B X 2 GHz SMY02 -

3 GHz SMIQ03E -

4 GHz SMIQ04B X

6 GHz SMIQ06B X

1) Requires firmware version V2.10.x or higher on the signal generator

2) Requires firmware version V1.10.x or higher on the signal generator

3) Requires the option SMR-B11 on the signal generator

4) Requires firmware version V3.20.200 or higher on the signal generator

4.3.3 Generator Setup Files

For each signal generator type to be controlled by the R&S FSV/A a generator setup file must be configured and stored on the R&S FSV/A. The setup file defines the frequency and power ranges supported by the generator, as well as information required for communication. For the signal generators listed in Chapter 4.3.2, "Overview of Sup-

ported Generators", on page 27, default setup files are provided. If necessary, these

files can be edited or duplicated for varying measurement setups or other instruments.

The existing setup files can be displayed in an editor in read-only mode directly from the "External Generator" configuration dialog box. From there, they can be edited and stored under a different name, and are then available on the R&S FSV/A.

(For details see the R&S FSV/A User Manual).

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4.3.4 Calibration Mechanism

A common measurement setup includes a signal generator, a device under test (DUT), and a signal and spectrum analyzer. Therefore, it is useful to measure the attenuation or gain caused by the cables and connectors from the signal generator and the signal analyzer in advance. The known level offsets can then be removed from the measurement results in order to obtain accurate information on the DUT.

Calculating the difference between the currently measured power and a reference trace is referred to as calibration. Thus, the measurement results from the controlled external generator - including the inherent distortions - can be used as a reference trace to calibrate the measurement setup.

The inherent frequency and power level distortions can be determined by connecting the R&S FSV/A to the signal generator. The R&S FSV/A sends a predefined list of frequencies to the signal generator (see also Chapter 4.3.7, "Coupling the Frequencies", on page 31). The signal generator then sends a signal with the specified level at each frequency in the predefined list. The R&S FSV/A measures the signal and determines the level offsets to the expected values.

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Saving calibration results

A reference dataset for the calibration results is stored internally as a table of value pairs (frequency/level), one for each sweep point. The measured offsets can then be used as calibration factors for subsequent measurement results.

The calibration can be performed using either transmission or reflection measurements. The selected type of measurement used to determine the reference trace is included in the reference dataset.

4.3.5 Normalization

Once the measurement setup has been calibrated and the reference trace is available, subsequent measurement results can be corrected according to the calibration factors, if necessary. This is done by subtracting the reference trace from the measurement results. This process is referred to as normalization and can be activated or deactivated as required. If normalization is activated, "NOR" is displayed in the channel bar, next to the indication that an external generator is being used ("Ext.Gen").The normalized trace from the calibration sweep is a constant 0 dB line, as <calibration trace> <reference trace> = 0.

As long as the same settings are used for measurement as for calibration, the normalized measurement results should not contain any inherent frequency or power distortions. Thus, the measured DUT values are very accurate.

Approximate normalization

As soon as any of the calibration measurement settings are changed, the stored reference trace will no longer be identical to the new measurement results. However, if the measurement settings do not deviate too much, the measurement results can still be normalized approximately using the stored reference trace. This is indicated by the "APX" label in the channel bar (instead of "NOR").

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This is the case if one or more of the following values deviate from the calibration settings:

●

Coupling (RBW, VBW, SWT)

●

Reference level, RF attenuation

●

Start or stop frequency

●

Output level of external generator

●

Detector (max. peak, min. peak, sample, etc.)

●

Frequency deviation at a maximum of 1001 points within the set sweep limits (corresponds to a doubling of the span)

Differences in level settings between the reference trace and the current instrument settings are taken into account automatically. If the span is reduced, a linear interpolation of the intermediate values is applied. If the span increases, the values at the left or right border of the reference dataset are extrapolated to the current start or stop frequency, i.e. the reference dataset is extended by constant values.

Thus, the instrument settings can be changed in a wide area without giving up normalization. This reduces the necessity to carry out a new normalization to a minimum.

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

If approximation becomes too poor, however, normalization is aborted and an error message is displayed (see Chapter 4.3.8, "Displayed Information and Errors", on page 34).

The normalized trace in the display

The normalized reference trace is also displayed in the spectrum diagram, by default at the top of the diagram (= 100% of the window height). It is indicated by a red line labeled "NOR", followed by the current reference value. However, it can be shifted vertically to reflect an attenuation or gain caused by the measured DUT (see also "Shifting

the reference line (and normalized trace)" on page 31).

Restoring the calibration settings

If the measurement settings no longer match the instrument settings with which the calibration was performed (indicated by the "APX" or no label next to "Ext.TG" in the channel bar), you can restore the calibration settings, which are stored with the reference dataset on the R&S FSV/A.

Storing the normalized reference trace as a transducer factor

The (inverse) normalized reference trace can also be stored as a transducer factor for use in other R&S FSV/A applications that do not support external generator control. The normalized trace data is converted to a transducer with unit dB and stored in a file with the specified name and the suffix .trd under c:\r_s\instr\trd. The frequency points are allocated in equidistant steps between the start and stop frequency.

This is useful, for example, to determine the effects of a particular device component and then remove these effects from a subsequent measurement which includes this component.

For an example see the "External Generator Control: Measurement Examples" section in the R&S FSV/A User Manual.

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Note that the normalized measurement data is stored, not the original reference trace! Thus, if you store the normalized trace directly after calibration, without changing any settings, the transducer factor will be 0 dB for the entire span (by definition of the normalized trace).

4.3.6 Reference Trace, Reference Line and Reference Level

Reference trace

The calibration results are stored internally on the R&S FSV/A as a reference trace. For each measured sweep point the offset to the expected values is determined. If normalization is activated, the offsets in the reference trace are removed from the current measurement results to compensate for the inherent distortions.

Reference line

The reference line is defined by the Reference Value and Reference Position in the "External Generator" > "Source Calibration" settings. It is similar to the Reference

Level defined in the "Amplitude" settings. However, as opposed to the reference level,

this reference line only affects the y-axis scaling in the diagram, it has no effect on the expected input power level or the hardware settings.

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

The reference line determines the range and the scaling of the y-axis, just as the reference level does.

The normalized reference trace (0 dB directly after calibration) is displayed on this reference line, indicated by a red line in the diagram. By default, the reference line is displayed at the top of the diagram. If you shift the reference line, the normalized trace is shifted, as well.

Shifting the reference line (and normalized trace)

You can shift the reference line - and thus the normalized trace - in the result display by changing the Reference Position or the Reference Value .

If the DUT inserts a gain or an attenuation in the measurement, this effect can be reflected in the result display on the R&S FSV/A. To reflect a power offset in the measurement trace, change the Reference Value .

4.3.7 Coupling the Frequencies

As described in Chapter 4.3.5, "Normalization", on page 29, normalized measurement results are very accurate as long as the same settings are used as for calibration. Although approximate normalization is possible, it is important to consider the required frequencies for calibration in advance. The frequencies and levels supported by the connected signal generator are provided for reference with the interface configuration.

Two different methods are available to define the frequencies for calibration, that is to couple the frequencies of the R&S FSV/A with those of the signal generator:

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OffsetAnalyzerGenerator

atorDeno

Numerator

FF 

min

●

Manual coupling: a single frequency is defined

●

Automatic coupling: a series of frequencies is defined (one for each sweep point), based on the current frequency at the RF input of the R&S FSV/A; the RF frequency range covers the currently defined span of the R&S FSV/A (unless limited by the range of the signal generator)

Automatic coupling

If automatic coupling is used, the output frequency of the generator (source frequency) is calculated as follows:

Equation 4-1: Output frequency of the generator

Where:

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Generator

Analyzer

Numerator = multiplication factor for F

Denominator = division factor for F

Offset

= output frequency of the generator

= current frequency at the RF input of the R&S FSV/A

Analyzer

= frequency offset for F

, for example for frequency-converting measure-

Analyzer

ments or harmonics measurements

The value range for the offset depends on the selected generator. The default setting is 0 Hz. Offsets other than 0 Hz are indicated by the "FRQ" label in the channel bar (see also Chapter 4.3.8, "Displayed Information and Errors", on page 34).

Swept frequency range

The F

values for the calibration sweep start with the start frequency and end with

Analyzer

the stop frequency defined in the "Frequency" settings of the R&S FSV/A. The resulting output frequencies ( Result Frequency Start and Result Frequency Stop ) are displayed in "External Generator" > "Measurement Configuration" for reference.

If the resulting frequency range exceeds the allowed ranges of the signal generator, an error message is displayed (see Chapter 4.3.8, "Displayed Information and Errors", on page 34) and the Result Frequency Start and Result Frequency Stop values are corrected to comply with the range limits.

The calibration sweep nevertheless covers the entire span defined by the R&S FSV/A; however, no input is received from the generator outside the generator's defined limits.

TTL synchronization

Some Rohde & Schwarz signal generators support TTL synchronization when connected via GPIB. The TTL interface is included in the AUX control connector of the External Generator Control option.

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When pure GPIB connections are used between the R&S FSV/A and the signal generator, the R&S FSV/A sets the generator frequency for each frequency point individually via GPIB, and only when the setting procedure is finished, the R&S FSV/A can measure the next sweep point.

For generators with a TTL interface, the R&S FSV/A sends a list of the frequencies to be set to the generator before the beginning of the first sweep. Then the R&S FSV/A starts the sweep and the next frequency point is selected by both the R&S FSV/A and the generator using the TTL handshake line "TRIGGER". The R&S FSV/A can only measure a value when the generator signals the end of the setting procedure via the "BLANK" signal.

Reverse sweep

The frequency offset for automatic coupling can be used to sweep in the reverse direction. To do so, define a negative offset in the external generator measurement configuration. (Note that the frequency is defined as the unsigned value of the equation, thus a negative frequency is not possible.)

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

Example: Example for reverse sweep

AnalyzerStart

AnalyzerStop

Offset

= 100 MHz

= 200 MHz

= -300 MHz

Numerator = Denominator = 1 →F

GeneratorStart

→F

GeneratorStop

= 200 MHz = 100 MHz

If the offset is adjusted so that the sweep of the generator crosses the minimum generator frequency, a message is displayed in the status bar ("Reverse Sweep via min. Ext. Generator Frequency!").

Example: Example for reverse sweep via minimum frequency

AnalyzerStart

AnalyzerStop

Offset

min

= 100 MHz = 200 MHz

= -150 MHz

= 20 MHz

Numerator = Denominator = 1 →F

GeneratorStart

→F

GeneratorStop

= 50 MHz = 50 MHz via F

min

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4.3.8 Displayed Information and Errors

Channel bar

If external generator control is active, some additional information is displayed in the channel bar.

Label Description

EXT TG: <source power> External generator active; signal sent with <source power> level

LVL Power Offset (see " Source Offset " on page 59

FRQ Frequency Offset (see "(Automatic) Source Frequency (Numerator/Denomi-

NOR Normalization on;

APX (approximation) Normalization on;

Basics on I/Q Data Acquisition and Processing

Basics on External Generator Control

nator/Offset)" on page 60

No difference between reference setting and measurement

Deviation from the reference setting occurs

- Aborted normalization or no calibration performed yet

Error and status messages

The following status and error messages may occur during external generator control.

Message Description

"Ext. Generator GPIB Handshake Error!" / "Ext. Generator TCPIP Handshake Error!" / "Ext. Generator TTL Handshake Error!"

"Ext. Generator Limits Exceeded!" The allowed frequency or power ranges for the generator

"Reverse Sweep via min. Ext. Generator Frequency!"

"Ext. Generator File Syntax Error!" Syntax error in the generator setup file (see Chap-

"Ext. Generator Command Error!" Missing or wrong command in the generator setup file

"Ext. Generator Visa Error!" Error with Visa driver provided with installation (very

Connection to the generator is not possible, e.g. due to a cable damage or loose connection or wrong address.

were exceeded.

Reverse sweep is performed; frequencies are reduced to the minimum frequency, then increased again; see

"Reverse sweep" on page 33

ter 4.3.3, "Generator Setup Files", on page 28

(see Chapter 4.3.3, "Generator Setup Files", on page 28

unlikely)

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Overloading

At a reference level of -10 dBm and at an external generator output level of the same value, the R&S FSV/A operates without overrange reserve. That means the R&S FSV/A is in danger of being overloaded if a signal is applied whose amplitude is higher than the reference line. In this case, either the message "RF OVLD" for overload or "ADC OVLD" for exceeded display range (clipping of the trace at the upper diagram border = overrange) is displayed in the status line.

Overloading can be avoided as follows:

●

Reducing the output level of the external generator (" Source Power " on page 59 in "External Generator > Measurement Configuration")

●

Increasing the reference level ( Reference Level in the "Amplitude" menu)

4.4 Basics on Input from I/Q Data Files

Basics on I/Q Data Acquisition and Processing

Basics on Input from I/Q Data Files

The I/Q data to be evaluated in a particular R&S FSV/A application can not only be captured by the application itself, it can also be loaded from a file, provided it has the correct format. The file is then used as the input source for the application.

For example, you can capture I/Q data using the I/Q Analyzer application, store it to a file, and then analyze the signal parameters for that data later using the Pulse application (if available).

The I/Q data must be stored in a format with the file extension .iq.tar. For a detailed description see Chapter C, "I/Q Data File Format (iq-tar)", on page 286.

An application note on converting Rohde & Schwarz I/Q data files is available from the Rohde & Schwarz website:

1EF85: Converting R&S I/Q data files

For I/Q file input, the stored I/Q data remains available as input for any number of subsequent measurements. When the data is used as an input source, the data acquisition settings in the current application (attenuation, center frequency, measurement bandwidth, sample rate) can be ignored. As a result, these settings cannot be changed in the current application. Only the measurement time can be decreased, in order to perform measurements on an extract of the available data (from the beginning of the file) only.

When using input from an I/Q data file, the [RUN SINGLE] function starts a single measurement (i.e. analysis) of the stored I/Q data, while the [RUN CONT] function repeatedly analyzes the same data from the file.

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Sample iq.tar files

If you have the optional R&S FSV/A VSA application (R&S FSV3-K70), some sample iq.tar files are provided in the C:/R_S/Instr/user/vsa/DemoSignals directory on the R&S FSV/A.

Furthermore, you can create your own iq.tar files in the I/Q Analyzer, see Chap-

ter 7.2, "How to Export and Import I/Q Data", on page 125.

Pre-trigger and post-trigger samples

In applications that use pre-triggers or post-triggers, if no pre-trigger or post-trigger samples are specified in the I/Q data file, or too few trigger samples are provided to satisfy the requirements of the application, the missing pre- or post-trigger values are filled up with zeros. Superfluous samples in the file are dropped, if necessary. For pretrigger samples, values are filled up or omitted at the beginning of the capture buffer, for post-trigger samples, values are filled up or omitted at the end of the capture buffer.

Basics on I/Q Data Acquisition and Processing

Receiving and Providing Trigger Signals

4.5 IF and Video Signal Output

The measured IF signal or displayed video signal (i.e. the filtered and detected IF signal) can be provided at the IF output connector of the R&S FSV/A.

The IF output is a signal of the measured level at a specified frequency.

Restrictions

Note the following restrictions for data output:

●

IF and video output is only available in the time domain (zero span).

●

For I/Q data, only IF output is available.

●

IF output is not available if any of the following conditions apply: – The sample rate is larger than 200 MHz (upsampling)

4.6 Receiving and Providing Trigger Signals

Using one of the "Trigger Input / Output" connectors of the R&S FSV/A, the R&S FSV/A can use a signal from an external device as a trigger to capture data. Alternatively, the internal trigger signal used by the R&S FSV/A can be output for use by other connected devices. Using the same trigger on several devices is useful to synchronize the transmitted and received signals within a measurement.

For details on the connectors see the R&S FSV/A "Getting Started" manual.

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External trigger as input

If the trigger signal for the R&S FSV/A is provided by an external device, the trigger signal source must be connected to the R&S FSV/A and the trigger source must be defined as "External" in the R&S FSV/A.

Trigger output

The R&S FSV/A can provide output to another device either to pass on the internal trigger signal, or to indicate that the R&S FSV/A itself is ready to trigger.

The trigger signal can be output by the R&S FSV/A automatically, or manually by the user. If it is provided automatically, a high signal is output when the R&S FSV/A has triggered due to a sweep start ( "Device Triggered" ), or when the R&S FSV/A is ready to receive a trigger signal after a sweep start ( "Trigger Armed" ).

Manual triggering

If the trigger output signal is initiated manually, the length and level (high/low) of the trigger pulse is also user-definable. Note, however, that the trigger pulse level is always opposite to the constant signal level defined by the output "Level" setting, e.g. for "Level" = "High", a constant high signal is output to the connector until the "Send Trigger" button is selected. Then, a low pulse is provided.

Basics on I/Q Data Acquisition and Processing

I/Q Data Import and Export

4.7 I/Q Data Import and Export

Baseband signals mostly occur as so-called complex baseband signals, i.e. a signal representation that consists of two channels; the in phase (I) and the quadrature (Q) channel. Such signals are referred to as I/Q signals. The complete modulation information and even distortion that originates from the RF, IF or baseband domains can be analyzed in the I/Q baseband.

Importing and exporting I/Q signals is useful for various applications:

●

Generating and saving I/Q signals in an RF or baseband signal generator or in external software tools to analyze them with the R&S FSV/A later

●

Capturing and saving I/Q signals with an RF or baseband signal analyzer to analyze them with the R&S FSV/A or an external software tool later

As opposed to storing trace data, which may be averaged or restricted to peak values, I/Q data is stored as it was captured, without further processing. The data is stored as complex values in 32-bit floating-point format. Multi-channel data is not supported. The I/Q data is stored in a format with the file extension .iq.tar.

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An application note on converting Rohde & Schwarz I/Q data files is available from the Rohde & Schwarz website:

1EF85: Converting R&S I/Q data files

The export functions are available in the "Save/Recall" menu which is displayed when you select the "Save" or "Open" icon in the toolbar (see Chapter 5.2, "Import/

Export Functions", on page 47). The import functions are available in the "I/Q File"

dialog box (see Chapter 5.3.1.2, "Settings for Input from I/Q Data Files", on page 53).

4.8 Basics on FFT

The I/Q Analyzer measures the power of the signal input over time. To convert the time domain signal to a frequency spectrum, an FFT (Fast Fourier Transformation) is performed which converts a vector of input values into a discrete spectrum of frequencies.

Basics on I/Q Data Acquisition and Processing

Basics on FFT

4.8.1 Window Functions

The Fourier transformation is not performed on the entire captured data in one step. Only a limited number of samples is used to calculate an individual result. This process is called windowing.

After sampling in the time domain, each window is multiplied with a specific window function. Windowing helps minimize the discontinuities at the end of the measured signal interval and thus reduces the effect of spectral leakage, increasing the frequency resolution.

t[s]

FFT

f[Hz]

Various different window functions are provided in the R&S FSV/A to suit different input signals. Each of the window functions has specific characteristics, including some advantages and some trade-offs. Consider these characteristics to find the optimum solution for the measurement task.

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Ignoring the window function - rectangular window

The rectangular window function is in effect not a function at all, it maintains the original sampled data. This may be useful to minimize the required bandwidth. However, be aware that if the window does not contain exactly one period of your signal, heavy sidelobes may occur, which do not exist in the original signal.

Table 4-2: Characteristics of typical FFT window functions

Basics on I/Q Data Acquisition and Processing

Basics on FFT

Window type Frequency

Rectangular Best Worst Worst No function applied.

Blackman-Harris (default)

Gauss (Alpha = 0.4)

Flattop Worst Best Good Accurate single tone measurements

5-Term Good Good Best Measurements with very high

4.8.2 Overlapping

The I/Q Analyzer calculates multiple FFTs per measurement by dividing one captured record into several windows. Furthermore, the I/Q Analyzer allows consecutive windows to overlap. Overlapping "reuses" samples that were already used to calculate the preceding FFT result.

Magnitude

resolution

Good Good Good Harmonic detection and spurious

Good Good Good Weak signals and short duration

resolution

Sidelobe suppression

Measurement recommendation

Separation of two tones with almost equal amplitudes and a small frequency distance

emission detection

dynamic range

In advanced FFT mode with averaging, the overlapping factor can be set freely. The higher the overlap factor, the more windows are used. This leads to more individual results and improves detection of transient signal effects. However, it also extends the

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duration of the calculation. The size of the window can be defined manually according to the record length, the overlap factor, and the FFT length.

An FFT overlap of 67%, for example, means the second FFT calculation uses the last 67% of the data of the first FFT. It uses only 33% new data. The third FFT still covers 33% of the first FFT and 67% of the second FFT, and so on.

Figure 4-6: Overlapping FFTs

In "Manual" or "Auto" FFT mode, an FFT length of 4096 and a window length of 4096 (or the record length, if shorter) is used to calculate the spectrum.

Basics on I/Q Data Acquisition and Processing

Basics on FFT

Combining results - trace detector

If the record length permits, multiple overlapping windows are calculated and combined to create the final spectrum using the selected trace detector. If necessary, the trace detector is also used to reduce the number of calculated frequency points (defined by the FFT length) to the defined number of sweep points. By default, the Autopeak trace detector is used.

Since the frequency points are reduced to the number of sweep points, using a detector other than "Auto Peak" and fewer than 4096 sweep points can lead to false level results.

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4.8.3 Dependencies Between FFT Parameters

FFT analysis in the R&S FSV/A is highly configurable. Several parameters, including the resolution bandwidth, record length, and FFT length, are user-definable. Note, however, that several parameters are correlated and not all can be configured independently of the others.

Record Length

Defines the number of I/Q samples to capture. By default, the number of sweep points is used. The record length is calculated as the measurement time multiplied by the sample rate.

If you change the record length, the Meas Time is automatically changed, as well.

For FFTs using only a single window ( "Single" mode), the record length (which is then identical to the FFT length) must not exceed 512k.

FFT Length

Defines the number of frequency points determined by each FFT calculation. The more points are used, the higher the resolution in the spectrum becomes, but the longer the calculation takes.

Basics on I/Q Data Acquisition and Processing

Basics on FFT

In "Auto" or "Manual" mode, an FFT length of 4096 is used.

In advanced FFT mode, the FFT length is user-definable. If you use the arrow keys or the rotary knob to change the FFT length, the value is incremented or decremented by powers of 2. If you enter the value manually, any integer value from 3 to 524288 is available.

If the FFT length is longer than the Window Length the sample data is filled up with zeros up to the FFT length. The FFT is then performed using interpolated frequency points.

For an FFT length that is not a power of 2, a DFT (discrete Fourier transform) is performed, which requires more time for calculation, but avoids the effects of interpolation.

To display all calculated frequency points (defined by the FFT length), the number of sweep points is set to the FFT length automatically in advanced FFT mode.

Window Length

Defines the number of samples to be included in a single window in averaging mode. (In single mode, the window length corresponds to the " Record Length " on page 79.)

Values from 3 to 4096 are available in "Manual" mode; in "Advanced" FFT mode, values from 3 to 524288 are available. However, the window length must not be longer than the FFT Length .

If the window length is shorter than the FFT Length , the sample data is filled up with zeros up to the FFT length.

If the window length is longer than the Record Length (that is, not enough samples are available), a window length the size of the Record Length is used for calculation.

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LengthWindow

RateSample

BandwidthNormalizedRBW 

RateSample*BandwidthNormalized

RBW

max



 

LengthcordRe,4096min

RateSampleBandwidth*Normalized

RBW

min



The window length and the Window Overlap determine how many FFT calculations must be performed for each record in averaging mode (see " Transformation Algorithm

" on page 81).

4.8.4 Frequency Resolution of FFT Results - RBW

The resolution bandwidth defines the minimum frequency separation at which the individual components of a spectrum can be distinguished. Small values result in high precision, as the distance between two distinguishable frequencies is small. Higher values decrease the precision, but increase measurement speed.

The RBW is determined by the following equation:

Equation 4-2: Definition of RBW

(Note: The normalized bandwidth is a fixed value that takes the noise bandwidth of the window function into consideration.)

Basics on I/Q Data Acquisition and Processing

Basics on FFT

The maximum RBW is restricted by the Analysis Bandwidth , or by the following equation, whichever is higher:

If a higher spectral resolution is required, the number of samples must be increased by using a higher sample rate or longer record length.

The minimum achievable RBW depends on the sample rate and record length, according to the following equation:

To simplify operation, some parameters are coupled and automatically calculated, such as record length and RBW.

RBW mode

Depending on the selected RBW mode, the resolution bandwidth is either determined automatically or can be defined manually.

Auto mode:

This is the default mode in the I/Q Analyzer. The RBW is determined automatically depending on the Sample Rate and Window Length , where the window length corresponds to the Record Length , or a maximum of 4096.

If the record length is larger than the window length, multiple windows are combined; the FFT length is 4096.

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A Flatop window function is used.

Manual mode:

The RBW is user-definable.

The Window Length is adapted to comply with Equation 4-2. Since only window lengths with integer values can be employed, the Sample Rate is adapted, if necessary, to obtain an integer window length value.

If the record length is larger than the window length, multiple windows are combined; the FFT length is 4096.

A Flatop window function is used.

Advanced FFT mode

The RBW is determined by the advanced FFT parameters, depending on the selected

FFT Calculation Methods method.

4.8.5 FFT Calculation Methods

Basics on I/Q Data Acquisition and Processing

Basics on FFT

FFT calculation can be performed using different methods.

Single

In single mode, one FFT is calculated for the entire record length, that means the window length is identical to the record length.

If the defined FFT Length is larger than the record length, zeros are appended to the captured data to reach the FFT length.

Figure 4-7: FFT parameters for single FFT calculation

Averaging

In averaging mode, several overlapping FFTs are calculated for each record; the results are combined to determine the final FFT result for the record.

The number of FFTs to be combined is determined by the Window Overlap and the

Window Length .

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Figure 4-8: FFT parameters for averaged FFT calculation

Basics on I/Q Data Acquisition and Processing

Basics on FFT

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5 Configuration

Access: [MODE] > "I/Q Analyzer"

The I/Q Analyzer is a special application on the R&S FSV/A.

When you switch to an I/Q Analyzer channel the first time, a set of parameters is passed on from the currently active application. After initial setup, the parameters for the channel are stored upon exiting and restored upon re-entering the channel. Thus, you can switch between applications quickly and easily.

When you activate a channel for the I/Q Analyzer application, data acquisition from the input signal is started automatically with the default configuration. The "I/Q Analyzer" menu is displayed and provides access to the most important configuration functions.

The remote commands required to perform these tasks are described in Chapter 8,

"Remote Commands to Perform Measurements with I/Q Data", on page 128.

Importing and Exporting I/Q Data

The I/Q data to be evaluated in the I/Q Analyzer application can not only be captured by the I/Q Analyzer itself, it can also be imported to the R&S FSV/A, provided it has the correct format. Furthermore, the captured I/Q data from the I/Q Analyzer can be exported for further analysis in external applications.

For details see Chapter 4.7, "I/Q Data Import and Export", on page 37.

Configuration

Configuration Overview

● Configuration Overview...........................................................................................45

● Import/Export Functions..........................................................................................47

● Data Input and Output Settings...............................................................................50

● Amplitude................................................................................................................ 65

● Frequency Settings................................................................................................. 70

● Trigger Settings.......................................................................................................71

● Data Acquisition and Bandwidth Settings............................................................... 77

● Display Configuration..............................................................................................85

● Adjusting Settings Automatically.............................................................................85

5.1 Configuration Overview

Access: all menus

Throughout the channel configuration, an overview of the most important currently defined settings is provided in the "Overview" .

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Multiple access paths to functionality

The easiest way to configure a channel is via the "Overview" dialog box, which is available from all menus.

Alternatively, you can access the individual dialog boxes from the corresponding menu items, or via tools in the toolbars, if available.

In this documentation, only the most convenient method of accessing the dialog boxes is indicated - usually via the "Overview" .

Configuration

Configuration Overview

Figure 5-1: Configuration Overview for I/Q Analyzer Master

In addition to the main measurement settings, the "Overview" provides quick access to the main settings dialog boxes. The individual configuration steps are displayed in the order of the data flow. Thus, you can easily configure an entire channel from input over processing to output and analysis by stepping through the dialog boxes as indicated in the "Overview" .

The "Overview" for the I/Q Analyzer provides quick access to the following configuration dialog boxes (listed in the recommended order of processing):

1. Input settings See Chapter 5.3.1, "Input Source Settings", on page 51

2. Amplitude settings See Chapter 5.4, "Amplitude", on page 65

3. Frequency settings See Chapter 5.5, "Frequency Settings", on page 70

4. Optionally, Trigger/Gate settings See Chapter 5.6, "Trigger Settings", on page 71

5. Bandwidth settings

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See Chapter 5.7, "Data Acquisition and Bandwidth Settings", on page 77

6. Optionally, output settings See Chapter 5.3.2, "Output Settings", on page 64

7. Analysis settings and functions See Chapter 6, "Analysis", on page 89

8. Display configuration See Chapter 5.8, "Display Configuration", on page 85

To configure settings

► Select any button in the "Overview" to open the corresponding dialog box.

Select a setting in the channel bar (at the top of the channel tab) to change a specific setting.

For step-by-step instructions on configuring I/Q Analyzer measurements, see Chap-

ter 7.1, "How to Perform Measurements in the I/Q Analyzer Application", on page 125.

Configuration

Import/Export Functions

Preset Channel

Select the "Preset Channel" button in the lower left-hand corner of the "Overview" to restore all measurement settings in the current channel to their default values.

Do not confuse the "Preset Channel" button with the [Preset] key, which restores the entire instrument to its default values and thus closes all channels on the R&S FSV/A (except for the default channel)!

Remote command:

SYSTem:PRESet:CHANnel[:EXEC] on page 138

Specific Settings for

The channel may contain several windows for different results. Thus, the settings indicated in the "Overview" and configured in the dialog boxes vary depending on the selected window.

Select an active window from the "Specific Settings for" selection list that is displayed in the "Overview" and in all window-specific configuration dialog boxes.

The "Overview" and dialog boxes are updated to indicate the settings for the selected window.

5.2 Import/Export Functions

Access: "Save" / "Open" icon in the toolbar > "Import" / "Export"

Access (Import I/Q data): [Input Output] > "Input Source Config" > "I/Q File"

The R&S FSV/A provides various evaluation methods for the results of the performed measurements. However, you may want to evaluate the data with further, external applications. In this case, you can export the measurement data to a standard format file (ASCII or XML). Some of the data stored in these formats can also be re-imported to the R&S FSV/A for further evaluation later, for example in other applications.

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The following data types can be exported (depending on the application):

●

Trace data

●

Table results, such as result summaries, marker peak lists etc.

●

I/Q data

I/Q data can only be imported and exported in applications that process I/Q data, such as the I/Q Analyzer or optional applications.

See the corresponding user manuals for those applications for details.

Exporting I/Q data is only possible in single sweep mode ( Continuous Sweep / Run

Cont ).

Importing I/Q data is also possible in continuous sweep mode. For more information about importing I/Q data files, see Chapter 5.3.1.2, "Settings for

Input from I/Q Data Files", on page 53.

Import ...........................................................................................................................48

Export ...........................................................................................................................48

└ Export Trace to ASCII File ............................................................................. 48

└ Trace Export Configuration ............................................................................50

└ I/Q Export .......................................................................................................50

Configuration

Import/Export Functions

└ File Type ..............................................................................................49

└ Decimal Separator ...............................................................................50

Import Access: "Save/Recall" > Import

Provides functions to import data. For more information about importing I/Q data files, see Chapter 5.3.1.2, "Settings for

Input from I/Q Data Files", on page 53.

Export Access: "Save/Recall" > Export

Opens a submenu to configure data export.

Export Trace to ASCII File ← Export

Saves the selected trace or all traces in the currently active result display to the specified file and directory in the selected ASCII format.

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Configuration

Import/Export Functions

Note: Secure user mode. In secure user mode, settings that are stored on the instrument are stored to volatile memory, which is restricted to 256 MB. Thus, a "memory limit reached" error can occur although the hard disk indicates that storage space is still available.

To store data permanently, select an external storage location such as a USB memory device.

For details, see "Protecting Data Using the Secure User Mode" in the "Data Management" section of the R&S FSV3000/ FSVA3000 base unit user manual.

Remote command:

MMEMory:STORe<n>:TRACe on page 273

File Type ← Export Trace to ASCII File ← Export

Determines the format of the ASCII file to be imported or exported. Depending on the external program in which the data file was created or is evaluated,

a comma-separated list (CSV) or a plain data format (DAT) file is required. Remote command:

FORMat:DEXPort:FORMat on page 271

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Decimal Separator ← Export Trace to ASCII File ← Export

Defines the decimal separator for floating-point numerals for the data export/import files. Evaluation programs require different separators in different languages.

Remote command:

FORMat:DEXPort:DSEParator on page 271

Trace Export Configuration ← Export

Opens the "Traces" dialog box to configure the trace and data export settings.

I/Q Export ← Export

Opens a file selection dialog box to define an export file name to which the I/Q data is stored. This function is only available in single sweep mode.

It is not available in the Spectrum application, only in applications that process I/Q data, such as the I/Q Analyzer or optional applications.

For details, see the description in the R&S FSV/A I/Q Analyzer User Manual ("Importing and Exporting I/Q Data").

Note: Storing large amounts of I/Q data (several Gigabytes) can exceed the available (internal) storage space on the R&S FSV/A. In this case, it can be necessary to use an external storage medium.

To store data permanently, select an external storage location such as a USB memory device.

For details, see "Protecting Data Using the Secure User Mode" in the "Data Management" section of the R&S FSV3000/ FSVA3000 base unit user manual.

Configuration

Data Input and Output Settings

Remote command:

MMEMory:STORe<n>:IQ:STATe on page 276 MMEMory:STORe<n>:IQ:COMMent on page 275

5.3 Data Input and Output Settings

Access: "Overview" > "Input" / "Output"

The R&S FSV/A can analyze signals from different input sources and provide various types of output (such as noise source control or trigger signals).

For background information on providing input and output or working with power sensors, see the R&S FSV/A User Manual.

● Input Source Settings..............................................................................................51

● Output Settings....................................................................................................... 64

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5.3.1 Input Source Settings

Access: "Overview" > "Input/Frontend" > "Input Source"

The input source determines which data the R&S FSV/A will analyze.

The default input source for the R&S FSV/A is "Radio Frequency" , i.e. the signal at the "RF Input" connector of the R&S FSV/A. If no additional options are installed, this is the only available input source.

● Radio Frequency Input............................................................................................51

● Settings for Input from I/Q Data Files......................................................................53

● Probe Settings.........................................................................................................54

● External Generator Control Settings....................................................................... 56

5.3.1.1 Radio Frequency Input

Access: "Overview" > "Input/Frontend" > "Input Source" > "Radio Frequency"

Configuration

Data Input and Output Settings

RF Input Protection

The RF input connector of the R&S FSV/A must be protected against signal levels that exceed the ranges specified in the data sheet. Therefore, the R&S FSV/A is equipped with an overload protection mechanism for DC and signal frequencies up to 30 MHz. This mechanism becomes active as soon as the power at the input mixer exceeds the specified limit. It ensures that the connection between RF input and input mixer is cut off.

When the overload protection is activated, an error message is displayed in the status bar ( "INPUT OVLD" ), and a message box informs you that the RF Input was disconnected. Furthermore, a status bit (bit 3) in the STAT:QUES:POW status register is set. In this case you must decrease the level at the RF input connector and then close the message box. Then measurement is possible again. Reactivating the RF input is also possible via the remote command INPut<ip>:ATTenuation:PROTection:RESet.

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Radio Frequency State ................................................................................................ 52

Input Coupling ..............................................................................................................52

Impedance ................................................................................................................... 52

Direct Path ................................................................................................................... 53

YIG-Preselector ............................................................................................................53

Radio Frequency State

Activates input from the "RF Input" connector. Remote command:

INPut<ip>:SELect on page 142

Input Coupling

The RF input of the R&S FSV/A can be coupled by alternating current (AC) or direct current (DC).

This function is not available for input from the optional Digital Baseband Interface or from the optional Analog Baseband Interface.

AC coupling blocks any DC voltage from the input signal. This is the default setting to prevent damage to the instrument. Very low frequencies in the input signal may be distorted.

However, some specifications require DC coupling. In this case, you must protect the instrument from damaging DC input voltages manually. For details, refer to the data sheet.

Remote command:

INPut<ip>:COUPling on page 140

Configuration

Data Input and Output Settings

Impedance

The R&S FSV/A has an internal impedance of 50 Ω. However, some applications use other impedance values. In order to match the impedance of an external application to the impedance of the R&S FSV/A, an impedance matching pad can be inserted at the input. If the type and impedance value of the used matching pad is known to the R&S FSV/A, it can convert the measured units accordingly so that the results are calculated correctly.

The impedance conversion does not affect the level of the output signals (such as IF, video, demod)

"50Ω" "75Ω"

"User"

Remote command:

INPut<ip>:IMPedance on page 141 INPut<ip>:IMPedance:PTYPe on page 141

(Default:) no conversion takes place The 50 Ω input impedance is transformed to a higher impedance

using a 75 Ω adapter of the selected "Pad Type": "Series-R" (default) or "MLP" (Minimum Loss Pad)

The 50 Ω input impedance is transformed to a user-defined impedance value according to the selected "Pad Type": "Series-R" (default) or "MLP" (Minimum Loss Pad)

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Direct Path

Enables or disables the use of the direct path for small frequencies. In spectrum analyzers, passive analog mixers are used for the first conversion of the

input signal. In such mixers, the LO signal is coupled into the IF path due to its limited isolation. The coupled LO signal becomes visible at the RF frequency 0 Hz. This effect is referred to as LO feedthrough.

To avoid the LO feedthrough the spectrum analyzer provides an alternative signal path to the A/D converter, referred to as the direct path. By default, the direct path is selected automatically for RF frequencies close to zero. However, this behavior can be disabled. If "Direct Path" is set to "Off" , the spectrum analyzer always uses the analog mixer path.

"Auto"

"Off" Remote command:

INPut<ip>:DPATh on page 140

Configuration

Data Input and Output Settings

(Default) The direct path is used automatically for frequencies close to zero.

The analog mixer path is always used.

YIG-Preselector

Activates or disables the YIG-preselector, if available on the R&S FSV/A. An internal YIG-preselector at the input of the R&S FSV/A ensures that image frequen-

cies are rejected. However, this is only possible for a restricted bandwidth. To use the maximum bandwidth for signal analysis you can disable the YIG-preselector at the input of the R&S FSV/A, which can lead to image-frequency display.

Note that the YIG-preselector is active only on frequencies greater than 7.5 GHz. Therefore, switching the YIG-preselector on or off has no effect if the frequency is below that value.

Note:

For the following measurements, the YIG-Preselector is off by default (if available).

●

I/Q Analyzer

●

GSM

●

VSA

Remote command:

INPut<ip>:FILTer:YIG[:STATe] on page 141

5.3.1.2 Settings for Input from I/Q Data Files

Access: "Overview" > "Input/Frontend" > "Input Source" > "I/Q File"

Or: [INPUT/OUTPUT] > "Input Source Config" > "Input Source" > "I/Q File"

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For details, see Chapter 4.4, "Basics on Input from I/Q Data Files", on page 35.

I/Q Input File State........................................................................................................ 54

Select I/Q data file ........................................................................................................54

I/Q Input File State

Enables input from the selected I/Q input file. If enabled, the application performs measurements on the data from this file. Thus,

most measurement settings related to data acquisition (attenuation, center frequency, measurement bandwidth, sample rate) cannot be changed. The measurement time can only be decreased, to perform measurements on an extract of the available data only.

Note: Even when the file input is disabled, the input file remains selected and can be enabled again quickly by changing the state.

Remote command:

INPut<ip>:SELect on page 142

Configuration

Data Input and Output Settings

Select I/Q data file

Opens a file selection dialog box to select an input file that contains I/Q data. The I/Q data must have a specific format (.iq.tar) as described in Chapter C, "I/Q

Data File Format (iq-tar)", on page 286.

The default storage location for I/Q data files is C:\R_S\INSTR\USER. Remote command:

INPut<ip>:FILE:PATH on page 143

5.3.1.3 Probe Settings

Access: [INPUT / OUTPUT] > "Input Source Config" > "Probes"

Data input for the measurement can be provided by probes if the optional R&S RT-ZA9 adapter is used.

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The detected type of probe, if any, is displayed.

For more information on using probes with an R&S FSV/A, see Chapter 4.2, "Using

Probes", on page 21.

For general information on the R&S®RT probes, see the device manuals.

Name.............................................................................................................................55

Serial Number............................................................................................................... 55

Part Number..................................................................................................................55

Type.............................................................................................................................. 55

Mode............................................................................................................................. 55

Common Mode Offset / Diff. Mode Offset / P Offset / N Offset / .................................. 56

Attenuation....................................................................................................................56

Microbutton Action ....................................................................................................... 56

Name

Probe name Remote command:

[SENSe:]PROBe<pb>:SETup:NAME? on page 146

Configuration

Data Input and Output Settings

Serial Number

Serial number of the probe Remote command:

[SENSe:]PROBe<pb>:ID:SRNumber? on page 144

Part Number

Rohde & Schwarz part number Remote command:

[SENSe:]PROBe<pb>:ID:PARTnumber? on page 143

Type

Type of probe:

●

Single-ended

●

Differential

●

Active Modular

Remote command:

[SENSe:]PROBe<pb>:SETup:TYPE? on page 148

Mode

Mode for multi-mode modular probes. Determines which voltage is measured. "DM-mode" "CM-mode"

"P-mode" "N-mode" Remote command:

[SENSe:]PROBe<pb>:SETup:PMODe on page 146

Voltage between the positive and negative input terminal Mean voltage between the positive and negative input terminal vs.

ground Voltage between the positive input terminal and ground Voltage between the negative input terminal and ground

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Common Mode Offset / Diff. Mode Offset / P Offset / N Offset /

Sets the offset for the probe, depending on the used mode (CM and DM mode both use the "Common Mode Offset"). The setting is only available if a differential (R&S RTZD) or modular (R&S RT-ZM) probe is connected to the R&S FSV/A.

If the probe is disconnected, the offset of the probe is reset to 0.0 V. Note: If the offset for DM-mode or CM-mode is changed, the offsets for the P-mode

and N-mode are adapted accordingly, and vice versa. Remote command:

[SENSe:]PROBe<pb>:SETup:CMOFfset on page 144 [SENSe:]PROBe<pb>:SETup:DMOFfset on page 145 [SENSe:]PROBe<pb>:SETup:NMOFfset on page 146 [SENSe:]PROBe<pb>:SETup:PMOFfset on page 147

Attenuation

Defines the attenuation applied to the input at the probe. This setting is only available for modular probes.

"10:1" "2:1" Remote command:

[SENSe:]PROBe<pb>:SETup:ATTRatio on page 144

Configuration

Data Input and Output Settings

Attenuation by 20 dB Attenuation by 6 dB

Microbutton Action

Active Rohde & Schwarz probes (except for R&S RT-ZS10E) have a configurable microbutton on the probe head. By pressing this button, you can perform an action on the instrument directly from the probe.

Select the action that you want to start from the probe: "Run Single" "No Action"

Remote command:

[SENSe:]PROBe<pb>:SETup:MODE on page 145

5.3.1.4 External Generator Control Settings

Access: [INPUT/OUPUT] > "External Generator Config"

The "External Generator" settings are available if the R&S FSV/A External Generator Control option is installed. For each measurement channel, you can configure one external generator. To switch between different configurations, define multiple measurement channels.

For more information on external generator control, see Chapter 4.3, "Basics on Exter-

nal Generator Control", on page 24.

Starts one data acquisition. Prevents unwanted actions due to unintended usage of the microbut-

ton.

● Interface Configuration Settings..............................................................................57

● Measurement Settings............................................................................................ 59

● Source Calibration Functions..................................................................................61

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Interface Configuration Settings

For more information on configuring interfaces, see the "Remote Control Interfaces and Protocols" section in the R&S FSV/A User Manual.

Configuration

Data Input and Output Settings

Generator Type ............................................................................................................57

Interface ....................................................................................................................... 57

TTL Handshake ............................................................................................................58

GPIB Address / TCPIP Address / Computer Name ..................................................... 58

Reference .....................................................................................................................58

Edit Generator Setup File .............................................................................................58

Frequency Min / Frequency Max ..................................................................................58

Level Min / Level Max .................................................................................................. 58

Generator Type

Selects the generator type and thus defines the generator setup file to use. For an overview of supported generators, see Chapter 4.3.2, "Overview of Supported

Generators", on page 27. For information on generator setup files, see Chapter 4.3.3, "Generator Setup Files", on page 28.

Remote command:

SYSTem:COMMunicate:RDEVice:GENerator<gen>:TYPE on page 154

Interface

Type of interface connection used. The following interfaces are currently supported:

●

GPIB

●

TCP/IP (not by all generators)

For details on which signal generators support which interfaces, see the documentation of the corresponding signal generator.

Remote command:

SYSTem:COMMunicate:RDEVice:GENerator<gen>:INTerface on page 153

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TTL Handshake

If available for the specified generator type, this option activates TTL synchronization via handshake for GPIB connections.

For more information on TTL synchronization, see "TTL synchronization" on page 32. For an overview of which generators support TTL synchronization see Chapter 4.3.2,

"Overview of Supported Generators", on page 27.

Remote command:

SYSTem:COMMunicate:RDEVice:GENerator<gen>:LINK on page 154

GPIB Address / TCPIP Address / Computer Name

For LAN connections: TCP/IP address of the signal generator For GPIB connections: GPIB address of the signal generator. Remote command:

SYSTem:COMMunicate:GPIB:RDEVice:GENerator<gen>:ADDRess on page 153 SYSTem:COMMunicate:TCPip:RDEVice:GENerator<gen>:ADDRess

on page 155

Configuration

Data Input and Output Settings

Reference

Selects the internal R&S FSV/A or an external frequency reference to synchronize the R&S FSV/A with the generator (default: internal).

Remote command:

SOURce<si>:EXTernal<gen>:ROSCillator[:SOURce] on page 153

Edit Generator Setup File

Displays the setup file for the currently selected Generator Type in read-only mode in an editor.

Although the existing setup files are displayed in read-only mode in the editor, they can be saved under a different name (using "File > SaveAs").

Be careful, however, to adhere to the required syntax and commands. Errors are only detected and displayed when you try to use the new generator (see also Chapter 4.3.8,

"Displayed Information and Errors", on page 34).

For details, see Chapter 4.3.3, "Generator Setup Files", on page 28.

Frequency Min / Frequency Max

For reference only: Lower and upper frequency limit for the generator.

Level Min / Level Max

For reference only: Lower and upper power limit for the generator.

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Measurement Settings

Configuration

Data Input and Output Settings

Source State ................................................................................................................ 59

Source Power ...............................................................................................................59

Source Offset ............................................................................................................... 59

Source Frequency Coupling..........................................................................................60

(Manual) Source Frequency..........................................................................................60

(Automatic) Source Frequency (Numerator/Denominator/Offset).................................60

Result Frequency Start ................................................................................................ 61

Result Frequency Stop .................................................................................................61

Source State

Activates or deactivates control of an external generator. Remote command:

SOURce<si>:EXTernal<gen>[:STATe] on page 152

Source Power

The output power of the external generator. The default output power is -20 dBm. The range is specified in the data sheet.

Remote command:

SOURce<si>:EXTernal<gen>:POWer[:LEVel] on page 151

Source Offset

Constant level offset for the external generator. Values from -200 dB to +200 dB in 1 dB steps are allowed. The default setting is 0 dB. Offsets are indicated by the "LVL" label in the channel bar (see also Chapter 4.3.8, "Displayed Information and Errors", on page 34).

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Using this offset, attenuators or amplifiers at the output connector of the external generator can be taken into account. This is useful, for example, for the displayed output power values on screen or during data entry. Positive offsets apply to an amplifier, while negative offsets apply to an attenuator after the external generator.

Remote command:

SOURce<si>:POWer[:LEVel][:IMMediate]:OFFSet on page 152

Source Frequency Coupling

Defines the frequency coupling mode between the R&S FSV/A and the generator. For more information on coupling frequencies, see Chapter 4.3.7, "Coupling the Fre-

quencies", on page 31.

"Auto"

"Manual"

Remote command:

SOURce<si>:EXTernal<gen>:FREQuency:COUPling[:STATe] on page 149

Configuration

Data Input and Output Settings

Default setting: a series of frequencies is defined (one for each sweep point), based on the current frequency at the RF input of the R&S FSV/A (see "(Automatic) Source Frequency (Numerator/Denom-

inator/Offset)" on page 60). The RF frequency range covers the cur-

rently defined span of the R&S FSV/A (unless limited by the range of the signal generator).

The generator uses a single fixed frequency, defined by (Manual)

Source Frequency which is displayed when you select "Manual" cou-

pling.

(Manual) Source Frequency

Defines the fixed frequency to be used by the generator. Remote command:

SOURce<si>:EXTernal<gen>:FREQuency on page 149

(Automatic) Source Frequency (Numerator/Denominator/Offset)

With automatic frequency coupling, a series of frequencies is defined (one for each sweep point), based on the current frequency at the RF input of the R&S FSV/A.

However, the frequency used by the generator may differ from the input from the R&S FSV/A. The RF frequency can be multiplied by a specified factor, or a frequency offset can be added, or both.

Note: The input for the generator frequency is not validated, i.e. you can enter any values. However, if the allowed frequency ranges of the generator are exceeded, an error message is displayed on the R&S FSV/A. The values for Result Frequency Start and

Result Frequency Stop are corrected to comply with the range limits.

The value range for the offset depends on the selected generator. The default setting is 0 Hz. Offsets <> 0 Hz are indicated by the "FRQ" label in the channel bar. Negative offsets can be used to define reverse sweeps.

For more information on coupling frequencies and reverse sweeps, see Chapter 4.3.7,

"Coupling the Frequencies", on page 31. For more information on error messages and

the channel bar, see Chapter 4.3.8, "Displayed Information and Errors", on page 34.

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Remote command:

SOURce<si>:EXTernal<gen>:FREQuency[:FACTor]:DENominator

on page 150

SOURce<si>:EXTernal<gen>:FREQuency[:FACTor]:NUMerator on page 150 SOURce<si>:EXTernal<gen>:FREQuency:OFFSet on page 151

Result Frequency Start

For reference only: The start frequency for the generator, calculated from the configured generator frequency and the start value defined for the R&S FSV/A.

Result Frequency Stop

For reference only: The stop frequency for the generator, calculated from the configured generator frequency and the stop value defined for the R&S FSV/A.

Source Calibration Functions

The calibration functions of the external generator are available only if external generator control is active (see " Source State " on page 59).

Configuration

Data Input and Output Settings

Calibrate Transmission..................................................................................................62

Calibrate Reflection Short............................................................................................. 62

Calibrate Reflection Open.............................................................................................62

Source Calibration Normalize ...................................................................................... 62

Recall ........................................................................................................................... 62

Save as Trd Factor .......................................................................................................63

Reference Position .......................................................................................................63

Reference Value ...........................................................................................................63

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Calibrate Transmission

Starts a transmission type measurement to determine a reference trace. This trace is used to calculate the difference for the normalized values.

For details, see Chapter 4.3.4, "Calibration Mechanism", on page 29. Remote command:

[SENSe:]CORRection:METHod on page 156

Calibrate Reflection Short

Starts a short-circuit reflection type measurement to determine a reference trace for calibration.

If both calibrations (open circuit, short circuit) are carried out, the calibration trace is calculated by averaging the two measurements. The order of the two calibration measurements is irrelevant.

Remote command:

[SENSe:]CORRection:METHod on page 156

Selects the reflection method.

[SENSe:]CORRection:COLLect[:ACQuire] on page 156

Starts the sweep for short-circuit calibration.

Configuration

Data Input and Output Settings

Calibrate Reflection Open

Starts an open-circuit reflection type measurement to determine a reference trace for calibration.

If both reflection-type calibrations (open circuit, short circuit) are carried out, the reference trace is calculated by averaging the two measurements. The order of the two calibration measurements is irrelevant.

Remote command:

[SENSe:]CORRection:METHod on page 156

Selects the reflection method.

[SENSe:]CORRection:COLLect[:ACQuire] on page 156

Starts the sweep for open-circuit calibration.

Source Calibration Normalize

Switches the normalization of measurement results on or off. This function is only available if the memory contains a reference trace, that is, after a calibration has been performed.

For details on normalization, see Chapter 4.3.5, "Normalization", on page 29. Remote command:

[SENSe:]CORRection[:STATe] on page 157

Recall

Restores the settings that were used during source calibration. This can be useful if instrument settings were changed after calibration (e.g. center frequency, frequency deviation, reference level, etc.).

Remote command:

[SENSe:]CORRection:RECall on page 157

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Save as Trd Factor

Uses the normalized measurement data to generate a transducer factor. The trace data is converted to a transducer with unit dB and stored in a file with the specified name and the suffix .trd under "C:\Program Files\Rohde-Schwarz\FSV3000\<version>\trd". The frequency points are allocated in equidistant steps between start and stop frequency. The generated transducer factor can be further adapted using the "Transducer" softkey in the [SETUP] menu.

For more information on transducers, see the "General Instrument Setup > Transducers" section in the R&S FSV/A User Manual.

This function is only available if Source Calibration Normalize is switched on. Note: Note that the normalized measurement data is used, not the reference trace!

Thus, if you store the normalized trace directly after calibration, without changing any settings, the transducer factor will be 0 dB for the entire span (by definition of the normalized trace).

Remote command:

[SENSe:]CORRection:TRANsducer:GENerate on page 157

Configuration

Data Input and Output Settings

Reference Position

Defines the position of the Result Frequency Stop in percent of the total y-axis range. The top of the diagram is 100%, the bottom is 0%. By default, the 0 dB line is displayed at the top of the diagram (100%).

This setting is only available if normalization is on (see " Source Calibration Normalize

" on page 62).

The reference line defined by the reference value and reference position is similar to the Reference Level defined in the "Amplitude" settings. However, this reference line only affects the y-axis scaling in the diagram, it has no effect on the expected input power level or the hardware settings.

The normalized trace (0 dB directly after calibration) is displayed on this reference line, indicated by a red line in the diagram. If you shift the reference line, the normalized trace is shifted, as well.

Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe]:RPOSition on page 180

Reference Value

Defines the reference value to be displayed at the specified Result Frequency Start . This setting can be used to shift the reference line and thus the normalized trace, simi-

lar to the Shifting the Display ( Offset ) defined in the "Amplitude" settings shifts the reference level in the display.

Shifting the normalized trace is useful, for example, to reflect an attenuation or gain caused by the measured DUT. If you then zoom into the diagram around the normalized trace, the measured trace still remains fully visible.

Remote command:

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:Y[:SCALe]:RVALue

on page 155

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5.3.2 Output Settings

Access: [Input/Output] > "Output"

The R&S FSV/A can provide output to special connectors for other devices.

For details on connectors, refer to the R&S FSV/A Getting Started manual, "Front / Rear Panel View" chapters.

How to provide trigger signals as output is described in detail in the R&S FSV/A User Manual.

Configuration

Data Input and Output Settings

Noise Source Control....................................................................................................64

Noise Source Control

The R&S FSV/A provides a connector ("NOISE SOURCE CONTROL") with a 28 V voltage supply for an external noise source. By switching the supply voltage for an external noise source on or off in the firmware, you can enable or disable the device as required.

External noise sources are useful when you are measuring power levels that fall below the noise floor of the R&S FSV/A itself, for example when measuring the noise level of an amplifier.

In this case, you can first connect an external noise source (whose noise power level is known in advance) to the R&S FSV/A and measure the total noise power. From this value you can determine the noise power of the R&S FSV/A. Then when you measure the power level of the actual DUT, you can deduct the known noise level from the total power to obtain the power level of the DUT.

Remote command:

DIAGnostic:SERVice:NSOurce on page 169

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5.4 Amplitude

Access: "Overview" > "Amplitude"

Amplitude settings are identical to the Spectrum application, except for a new scaling function for I/Q Vector and Real/Imag results (see " Y-Axis Max " on page 70).

For background information on amplitude settings see the R&S FSV/A User Manual.

5.4.1 Amplitude Settings

Access: "Overview" > "Amplitude"

Amplitude settings determine how the R&S FSV/A must process or display the expected input power levels.

Configuration

Amplitude

Reference Level

└ Shifting the Display ( Offset ).......................................................................... 66

└ Unit .................................................................................................................66

└ Setting the Reference Level Automatically ( Auto Level )...............................67

RF Attenuation ............................................................................................................. 67

└ Attenuation Mode / Value ...............................................................................67

Using Electronic Attenuation ........................................................................................67

Input Settings ............................................................................................................... 68

└ Preamplifier ....................................................................................................68

...........................................................................................................66

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Reference Level

Defines the expected maximum reference level. Signal levels above this value may not be measured correctly. This is indicated by an "IF Overload" status display.

The reference level can also be used to scale power diagrams; the reference level is then used as the maximum on the y-axis.

Since the hardware of the R&S FSV/A is adapted according to this value, it is recommended that you set the reference level close above the expected maximum signal level. Thus you ensure an optimum measurement (no compression, good signal-tonoise ratio).

Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe]:RLEVel on page 174

Shifting the Display ( Offset ) ← Reference Level

Defines an arithmetic level offset. This offset is added to the measured level. In some result displays, the scaling of the y-axis is changed accordingly.

Define an offset if the signal is attenuated or amplified before it is fed into the R&S FSV/A so the application shows correct power results. All displayed power level results are shifted by this value.

The setting range is ±200 dB in 0.01 dB steps. Note, however, that the internal reference level (used to adjust the hardware settings to

the expected signal) ignores any "Reference Level Offset" . Thus, it is important to keep in mind the actual power level the R&S FSV/A must handle. Do not rely on the displayed reference level (internal reference level = displayed reference level - offset).

Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe]:RLEVel:OFFSet on page 174

Configuration

Amplitude

Unit ← Reference Level

The R&S FSV/A measures the signal voltage at the RF input. In the default state, the level is displayed at a power level of 1 mW (= dBm). Via the

known input impedance (50 Ω or 75 Ω, see " Impedance " on page 52), conversion to other units is possible.

The following units are available and directly convertible:

●

dBm

●

dBmV

●

dBμV

●

dBμA

●

dBpW

●

Volt

●

Ampere

●

Watt

Remote command:

INPut<ip>:IMPedance on page 141 CALCulate<n>:UNIT:POWer on page 173

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Setting the Reference Level Automatically ( Auto Level ) ← Reference Level

Automatically determines a reference level which ensures that no overload occurs at the R&S FSV/A for the current input data. At the same time, the internal attenuators are adjusted so the signal-to-noise ratio is optimized, while signal compression and clipping are minimized.

To determine the required reference level, a level measurement is performed on the R&S FSV/A.

If necessary, you can optimize the reference level further. Decrease the attenuation level manually to the lowest possible value before an overload occurs, then decrease the reference level in the same way.

You can change the measurement time for the level measurement if necessary (see "

Changing the Automatic Measurement Time ( Meastime Manual )" on page 87).

Remote command:

[SENSe:]ADJust:LEVel on page 202

RF Attenuation

Defines the attenuation applied to the RF input of the R&S FSV/A.

Configuration

Amplitude

Attenuation Mode / Value ← RF Attenuation

The RF attenuation can be set automatically as a function of the selected reference level (Auto mode). This ensures that no overload occurs at the RF Input connector for the current reference level. It is the default setting.

By default and when no (optional) electronic attenuation is available, mechanical attenuation is applied.

This function is not available for input from the optional Digital Baseband Interface. In "Manual" mode, you can set the RF attenuation in 1 dB steps (down to 0 dB). Other

entries are rounded to the next integer value. The range is specified in the data sheet. If the defined reference level cannot be set for the defined RF attenuation, the reference level is adjusted accordingly and the warning "limit reached" is displayed.

NOTICE! Risk of hardware damage due to high power levels. When decreasing the attenuation manually, ensure that the power level does not exceed the maximum level allowed at the RF input, as an overload may lead to hardware damage.

Remote command:

INPut<ip>:ATTenuation on page 174 INPut<ip>:ATTenuation:AUTO on page 175

Using Electronic Attenuation

If the (optional) Electronic Attenuation hardware is installed on the R&S FSV/A, you can also activate an electronic attenuator.

In "Auto" mode, the settings are defined automatically; in "Manual" mode, you can define the mechanical and electronic attenuation separately.

Note: Electronic attenuation is not available for stop frequencies (or center frequencies in zero span) above 7 GHz. In "Auto" mode, RF attenuation is provided by the electronic attenuator as much as possible to reduce the amount of mechanical switching required. Mechanical attenuation may provide a better signal-to-noise ratio, however.

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When you switch off electronic attenuation, the RF attenuation is automatically set to the same mode (auto/manual) as the electronic attenuation was set to. Thus, the RF attenuation can be set to automatic mode, and the full attenuation is provided by the mechanical attenuator, if possible.

The electronic attenuation can be varied in 1 dB steps. If the electronic attenuation is on, the mechanical attenuation can be varied in 5 dB steps. Other entries are rounded to the next lower integer value.

If the defined reference level cannot be set for the given attenuation, the reference level is adjusted accordingly and the warning "limit reached" is displayed in the status bar.

Remote command:

INPut<ip>:EATT:STATe on page 177 INPut<ip>:EATT:AUTO on page 176 INPut<ip>:EATT on page 176

Input Settings

Some input settings affect the measured amplitude of the signal, as well. The parameters "Input Coupling" and "Impedance" are identical to those in the "Input"

settings. See Chapter 5.3.1, "Input Source Settings", on page 51.

Configuration

Amplitude

Preamplifier ← Input Settings

If the (optional) internal preamplifier hardware is installed, a preamplifier can be activated for the RF input signal.

You can use a preamplifier to analyze signals from DUTs with low output power. For R&S FSV/A3004, 3007, 3013, and 3030 models, the following settings are availa-

ble: "Off" "15 dB" "30 dB"

Deactivates the preamplifier. The RF input signal is amplified by about 15 dB. The RF input signal is amplified by about 30 dB.

For R&S FSV/A44 or higher models, the input signal is amplified by 30 dB if the preamplifier is activated. In this case, the preamplifier is only available under the following conditions:

●

In zero span, the maximum center frequency is 43.5 GHz

●

For frequency spans, the maximum stop frequency is 43.5 GHz

●

For I/Q measurements, the maximum center frequency depends on the analysis bandwidth:

≤

43.5 GHz - (<Analysis_bw> / 2)

center

If any of the conditions no longer apply after you change a setting, the preamplifier is automatically deactivated.

Remote command:

INPut<ip>:GAIN:STATe on page 178 INPut<ip>:GAIN[:VALue] on page 178

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5.4.2 Scaling the Y-Axis

The individual scaling settings that affect the vertical axis are described here.

Access: "Overview" > "Amplitude" > "Scale" tab

Or: [AMPT] > "Scale Config"

Configuration

Amplitude

Range ...........................................................................................................................69

Ref Level Position ........................................................................................................ 69

Scaling ......................................................................................................................... 70

Y-Axis Max ................................................................................................................... 70

Range

Defines the displayed y-axis range in dB. The default value is 100 dB. Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe] on page 179

Ref Level Position

Defines the reference level position, i.e. the position of the maximum AD converter value on the level axis in %.

0 % corresponds to the lower and 100 % to the upper limit of the diagram. Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe]:RPOSition on page 180

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Scaling

Defines the scaling method for the y-axis. "Logarithmic"

"Linear with Unit"

"Linear Percent"

"Absolute"

"Relative"

Remote command:

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:Y:SPACing on page 181 DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:Y[:SCALe]:MODE

on page 180

Configuration

Frequency Settings

Logarithmic scaling (only available for logarithmic units - dB..., and A, V, Watt)

Linear scaling in the unit of the measured signal

Linear scaling in percentages from 0 to 100

The labeling of the level lines refers to the absolute value of the reference level (not available for "Linear Percent" )

The scaling is in dB, relative to the reference level (only available for logarithmic units - dB...). The upper line of the grid (reference level) is always at 0 dB.

Y-Axis Max

Defines the maximum value of the y-axis in the currently selected diagram in either direction (in Volts). Thus, the y-axis scale starts at -<Y-Axis Max> and ends at +<Y-Axis Max>.

This command is only available if the evaluation mode for the I/Q Analyzer is set to "I/Q-Vector" or "Real/Imag (I/Q)" .

Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:Y[:SCALe] on page 179

5.5 Frequency Settings

Access: "Overview" > "Frequency"

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Center Frequency ........................................................................................................ 71

Center Frequency Stepsize ..........................................................................................71

Frequency Offset ..........................................................................................................71

Center Frequency

Defines the center frequency of the signal in Hertz. The allowed range of values for the center frequency depends on the frequency span. span > 0: span

and span

max

Remote command:

[SENSe:]FREQuency:CENTer on page 182

Center Frequency Stepsize

Defines the step size by which the center frequency is increased or decreased using the arrow keys.

The step size can be coupled to another value or it can be manually set to a fixed value.

"= Center"

"Manual"

Remote command:

[SENSe:]FREQuency:CENTer:STEP on page 182

Configuration

Trigger Settings

/2 ≤ f

min

depend on the instrument and are specified in the data sheet.

min

center

≤ f

– span

max

min

Sets the step size to the value of the center frequency. The used value is indicated in the "Value" field.

Defines a fixed step size for the center frequency. Enter the step size in the "Value" field.

Frequency Offset

Shifts the displayed frequency range along the x-axis by the defined offset. This parameter has no effect on the instrument's hardware, or on the captured data or

on data processing. It is simply a manipulation of the final results in which absolute frequency values are displayed. Thus, the x-axis of a spectrum display is shifted by a constant offset if it shows absolute frequencies. However, if it shows frequencies relative to the signal's center frequency, it is not shifted.

A frequency offset can be used to correct the display of a signal that is slightly distorted by the measurement setup, for example.

The allowed values range from -100 GHz to 100 GHz. The default setting is 0 Hz. Remote command:

[SENSe:]FREQuency:OFFSet on page 183

5.6 Trigger Settings

Access: "Overview" > "Trigger" ( > "Trigger In/Out" )

Trigger settings determine when the input signal is measured.

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External triggers from one of the "TRIGGER INPUT/OUTPUT" connectors on the R&S FSV/A are configured in a separate tab of the dialog box.

Configuration

Trigger Settings

Conventional gating as in the Spectrum application is not available for the I/Q Analyzer; however, a special gating mode is available in remote control, see Chap-

ter 8.4.4.3, "Configuring I/Q Gating", on page 191.

For step-by-step instructions on configuring triggered measurements, see the R&S FSV/A User Manual.

Trigger Source ..............................................................................................................73

└ Trigger Source ............................................................................................... 73

└ Free Run ..............................................................................................73

└ External Trigger 1/2.............................................................................. 73

└ IF Power .............................................................................................. 73

└ I/Q Power .............................................................................................74

└ Time .....................................................................................................74

└ Trigger Level ..................................................................................................74

└ Repetition Interval ..........................................................................................74

└ Drop-Out Time ............................................................................................... 74

└ Trigger Offset .................................................................................................75

└ Hysteresis ...................................................................................................... 75

└ Trigger Holdoff ............................................................................................... 75

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└ Slope ..............................................................................................................75

Trigger 1/2.....................................................................................................................76

└ Output Type ................................................................................................... 76

Trigger Source

The trigger settings define the beginning of a measurement.

Trigger Source ← Trigger Source

Selects the trigger source. If a trigger source other than "Free Run" is set, "TRG" is displayed in the channel bar and the trigger source is indicated.

Remote command:

TRIGger[:SEQuence]:SOURce on page 187

Free Run ← Trigger Source ← Trigger Source

No trigger source is considered. Data acquisition is started manually or automatically and continues until stopped explicitly.

Remote command: TRIG:SOUR IMM, see TRIGger[:SEQuence]:SOURce on page 187

Configuration

Trigger Settings

└ Level .................................................................................................... 77

└ Pulse Length ........................................................................................77

└ Send Trigger ........................................................................................77

External Trigger 1/2 ← Trigger Source ← Trigger Source

Data acquisition starts when the TTL signal fed into the specified input connector meets or exceeds the specified trigger level.

(See " Trigger Level " on page 74). Note: The "External Trigger 1" softkey automatically selects the trigger signal from the

Trigger 1 Input / Output connector on the front panel. In the I/Q Analyzer application, only "External Trigger 1" is supported.

For details, see the "Instrument Tour" chapter in the R&S FSV/A Getting Started manual.

"External Trigger 1"

Trigger signal from the Trigger 1 Input / Output connector.

"External Trigger 2"

Trigger signal from the Trigger 2 Input / Output connector. Note: Connector must be configured for "Input" in the "Output" configuration (See the R&S FSV/A User Manual).

Remote command: TRIG:SOUR EXT, TRIG:SOUR EXT2 See TRIGger[:SEQuence]:SOURce on page 187

IF Power ← Trigger Source ← Trigger Source

The R&S FSV/A starts capturing data as soon as the trigger level is exceeded around the third intermediate frequency.

For frequency sweeps, the third IF represents the start frequency. The trigger bandwidth at the third IF depends on the RBW and sweep type.

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For measurements on a fixed frequency (e.g. zero span or I/Q measurements), the third IF represents the center frequency.

This trigger source is only available for RF input. The available trigger levels depend on the RF attenuation and preamplification. A refer-

ence level offset, if defined, is also considered. For details on available trigger levels and trigger bandwidths, see the data sheet. Remote command:

TRIG:SOUR IFP, see TRIGger[:SEQuence]:SOURce on page 187

I/Q Power ← Trigger Source ← Trigger Source

This trigger source is only available in the I/Q Analyzer application and in applications that process I/Q data.

Triggers the measurement when the magnitude of the sampled I/Q data exceeds the trigger threshold.

The trigger bandwidth corresponds to the bandwidth setting for I/Q data acquisition. (See " Analysis Bandwidth " on page 79). Remote command:

TRIG:SOUR IQP, see TRIGger[:SEQuence]:SOURce on page 187

Configuration

Trigger Settings

Time ← Trigger Source ← Trigger Source

Triggers in a specified repetition interval. Remote command:

TRIG:SOUR TIME, see TRIGger[:SEQuence]:SOURce on page 187

Trigger Level ← Trigger Source

Defines the trigger level for the specified trigger source. For details on supported trigger levels, see the data sheet. Remote command:

TRIGger[:SEQuence]:LEVel:IFPower on page 186 TRIGger[:SEQuence]:LEVel:IQPower on page 186 TRIGger<tp>[:SEQuence]:LEVel[:EXTernal<port>] on page 185

Repetition Interval ← Trigger Source

Defines the repetition interval for a time trigger. The shortest interval is 2 ms. The repetition interval should be set to the exact pulse period, burst length, frame

length or other repetitive signal characteristic. Remote command:

TRIGger[:SEQuence]:TIME:RINTerval on page 188

Drop-Out Time ← Trigger Source

Defines the time the input signal must stay below the trigger level before triggering again.

Remote command:

TRIGger[:SEQuence]:DTIMe on page 184

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Trigger Offset ← Trigger Source

Defines the time offset between the trigger event and the start of the sweep.

Offset > 0: Start of the sweep is delayed

Offset < 0: Sweep starts earlier (pretrigger)

Tip: To determine the trigger point in the sample (for "External" or "IF Power" trigger source), use the TRACe:IQ:TPISample? command.

For the "Time" trigger source, this function is not available. Remote command:

TRIGger[:SEQuence]:HOLDoff[:TIME] on page 184

Hysteresis ← Trigger Source

Defines the distance in dB to the trigger level that the trigger source must exceed before a trigger event occurs. Setting a hysteresis avoids unwanted trigger events caused by noise oscillation around the trigger level.

This setting is only available for "IF Power" trigger sources. The range of the value is between 3 dB and 50 dB with a step width of 1 dB.

Configuration

Trigger Settings

Only possible for zero span (e.g. I/Q Analyzer application) and gated trigger switched off Maximum allowed range limited by the sweep time: Pretrigger

= sweep time

max

Remote command:

TRIGger[:SEQuence]:IFPower:HYSTeresis on page 185

Trigger Holdoff ← Trigger Source

Defines the minimum time (in seconds) that must pass between two trigger events. Trigger events that occur during the holdoff time are ignored.

Remote command:

TRIGger[:SEQuence]:IFPower:HOLDoff on page 184

Slope ← Trigger Source

For all trigger sources except time, you can define whether triggering occurs when the signal rises to the trigger level or falls down to it.

For gated measurements in "Edge" mode, the slope also defines whether the gate starts on a falling or rising edge.

Remote command:

TRIGger[:SEQuence]:SLOPe on page 186

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Trigger 1/2

Defines the usage of the variable Trigger Input/Output connectors, where: "Trigger 2" : Trigger Input/Output connector on the front panel "Trigger 3" : Trigger 3 Input/Output connector on the rear panel Defines the usage of the variable Trigger Aux connector on the rear panel. (Trigger 1 is INPUT only.) Note: Providing trigger signals as output is described in detail in the R&S FSV/A User

Manual. "Input"

"Output"

Remote command:

OUTPut<up>:TRIGger<tp>:DIRection on page 188

Configuration

Trigger Settings

The signal at the connector is used as an external trigger source by the R&S FSV/A. Trigger input parameters are available in the "Trigger" dialog box.

The R&S FSV/A sends a trigger signal to the output connector to be used by connected devices. Further trigger parameters are available for the connector.

Output Type ← Trigger 1/2

Type of signal to be sent to the output "Trigger Off"

"Device Triggered"

"Trigger Armed"

Deactivates the output. (Only for Trigger 3, for which only output is supported.)

(Default) Sends a trigger when the R&S FSV/A triggers.

Sends a (high level) trigger when the R&S FSV/A is in "Ready for trigger" state. This state is indicated by a status bit in the STATus:OPERation register (bit 5), as well as by a low-level signal at the AUX port (pin 9). For details, see the description of the STATus:OPERation register in the R&S FSV/A User Manual and the description of the AUX port in the R&S FSV/A Getting Started manual.

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Configuration

Data Acquisition and Bandwidth Settings

"User Defined"

Remote command:

OUTPut<up>:TRIGger<tp>:OTYPe on page 189

Level ← Output Type ← Trigger 1/2

Defines whether a high (1) or low (0) constant signal is sent to the trigger output connector.

The trigger pulse level is always opposite to the constant signal level defined here. For example, for "Level = High", a constant high signal is output to the connector until you select the Send Trigger function. Then, a low pulse is provided.

Remote command:

OUTPut<up>:TRIGger<tp>:LEVel on page 189

Pulse Length ← Output Type ← Trigger 1/2

Defines the duration of the pulse (pulse width) sent as a trigger to the output connector. Remote command:

OUTPut:TRIGger<tp>:PULSe:LENGth on page 190

Sends a trigger when you select the "Send Trigger" button. In this case, further parameters are available for the output signal.

Send Trigger ← Output Type ← Trigger 1/2

Sends a user-defined trigger to the output connector immediately. Note that the trigger pulse level is always opposite to the constant signal level defined

by the output Level setting. For example, for "Level" = "High", a constant high signal is output to the connector until you select the "Send Trigger" function. Then, a low pulse is sent.

Which pulse level will be sent is indicated by a graphic on the button. Remote command:

OUTPut:TRIGger<tp>:PULSe:IMMediate on page 190

5.7 Data Acquisition and Bandwidth Settings

Access: "Overview" > "Bandwidth"

● Data Acquisition...................................................................................................... 78

● Sweep Settings....................................................................................................... 82

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5.7.1 Data Acquisition

Access: "Overview" > "Bandwidth" > "Data Acquisition" tab

The data acquisition settings define which parts of the input signal are captured for further evaluation in the applications.

Configuration

Data Acquisition and Bandwidth Settings

Figure 5-2: Data acquisition settings with advanced FFT parameters

The remote commands required to perform these tasks are described in Chapter 8.4.5,

"Configuring Data Acquisition", on page 193.

Sample Rate ................................................................................................................ 79

Analysis Bandwidth ......................................................................................................79

Maximum Bandwidth ....................................................................................................79

Meas Time ....................................................................................................................79

Record Length ..............................................................................................................79

Swap I/Q ...................................................................................................................... 80

RBW .............................................................................................................................80

Advanced FFT mode / Basic Settings ..........................................................................81

└ Transformation Algorithm ...............................................................................81

└ FFT Length .................................................................................................... 81

└ Window Function ........................................................................................... 81

└ Window Overlap .............................................................................................81

└ Window Length .............................................................................................. 81

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Sample Rate

Defines the I/Q data sample rate of the R&S FSV/A. This value is dependent on the defined Analysis Bandwidth and the defined signal source.

sample rate = analysis bandwidth / 0.8

For details on the dependencies see Chapter 4.1.1, "Sample Rate and Maximum Usa-

ble I/Q Bandwidth for RF Input", on page 18.

Remote command:

TRACe:IQ:SRATe on page 198

Analysis Bandwidth

Defines the flat, usable bandwidth of the final I/Q data. This value is dependent on the defined Sample Rate and the defined signal source.

analysis bandwidth = 0.8 * sample rate

Remote command:

TRACe:IQ:BWIDth on page 196

Maximum Bandwidth

Defines the maximum bandwidth to be used by the R&S FSV/A for I/Q data acquisition.

Configuration

Data Acquisition and Bandwidth Settings

This setting is only available if a bandwidth extension option larger than 40 MHz is installed, and only for sample rates (that is: <SymbolRate>*<CaptureOverview>) up to 128 MHz. Otherwise, the maximum bandwidth is determined automatically.

For details on the maximum bandwidth see Chapter 4.1.1, "Sample Rate and Maxi-

mum Usable I/Q Bandwidth for RF Input", on page 18.

"Auto"

"40 MHz" "200 MHz" Remote command:

TRACe:IQ:WBANd[:STATe] on page 199 TRACe:IQ:WBANd:MBWidth on page 199

Meas Time

Defines the I/Q acquisition time. By default, the measurement time is calculated as the number of I/Q samples ( "Record Length" ) divided by the sample rate. If you change the measurement time, the Record Length is automatically changed, as well.

Remote command:

[SENSe:]SWEep:TIME on page 215

(Default) All installed bandwidth extension options are enabled. The currently available maximum bandwidth is allowed. (See Chapter 4.1.1, "Sample Rate and Maximum Usable I/Q Band-

width for RF Input", on page 18).

Restricts the analysis bandwidth to a maximum of 40 MHz. Restricts the analysis bandwidth to a maximum of 200 MHz.

Record Length

Defines the number of I/Q samples to record. By default, the number of sweep points is used. The record length is calculated as the measurement time multiplied by the sample rate. If you change the record length, the Meas Time is automatically changed, as well.

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Note: For the I/Q vector result display, the number of I/Q samples to record ( "Record

Length" ) must be identical to the number of trace points to be displayed ("Sweep Points"). Thus, the sweep points are not editable for this result display. If the "Record Length" is edited, the sweep points are adapted automatically.

Remote command:

TRACe:IQ:RLENgth on page 196 TRACe:IQ:SET on page 197

Swap I/Q

Activates or deactivates the inverted I/Q modulation. If the I and Q parts of the signal from the DUT are interchanged, the R&S FSV/A can do the same to compensate for it.

On I and Q signals are interchanged

Inverted sideband, Q+j*I

Off I and Q signals are not interchanged

Normal sideband, I+j*Q

Remote command:

[SENSe:]SWAPiq on page 196

Configuration

Data Acquisition and Bandwidth Settings

RBW

Defines the resolution bandwidth for Spectrum results. The available RBW values depend on the sample rate and record length.

(See Chapter 4.8.4, "Frequency Resolution of FFT Results - RBW", on page 42). Depending on the selected RBW mode, the value is either determined automatically or

can be defined manually. As soon as you enter a value in the input field, the RBW mode is changed to "Manual" .

If the "Advanced Fourier Transformation Params" option is enabled, advanced FFT mode is selected and the RBW cannot be defined directly.

Note that the RBW is correlated with the Sample Rate and Record Length (and possibly the Window Function and Window Length ). Changing any one of these parameters may cause a change to one or more of the other parameters. For more information see

Chapter 4.8, "Basics on FFT", on page 38.

"Auto mode"

(Default) The RBW is determined automatically depending on the

Sample Rate and Record Length .

"Manual mode"

The RBW can be defined by the user. The user-defined RBW is used and the Window Length (and possibly

Sample Rate ) are adapted accordingly.

"Advanced FFT mode"

This mode is used if the "Advanced Fourier Transformation Params" option is enabled. The RBW is determined by the advanced FFT parameters.

Remote command:

[SENSe:]IQ:BWIDth:MODE on page 193 [SENSe:]IQ:BWIDth:RESolution on page 194

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Advanced FFT mode / Basic Settings

Shows or hides the "Advanced Fourier Transformation" parameters in the "Data Acquisition" dialog box.

Note that if the advanced FFT mode is used, the RBW settings are not available.

Transformation Algorithm ← Advanced FFT mode / Basic Settings

Defines the FFT calculation method. "Single"

"Averaging"

Remote command:

[SENSe:]IQ:FFT:ALGorithm on page 194

Configuration

Data Acquisition and Bandwidth Settings

One FFT is calculated for the entire record length; if the FFT Length is larger than the record length, zeros are appended to the captured data.

Several overlapping FFTs are calculated for each record; the results are combined to determine the final FFT result for the record. The number of FFTs to be averaged is determined by the Window Overlap and the Window Length .

FFT Length ← Advanced FFT mode / Basic Settings

Defines the number of frequency points determined by each FFT calculation. The more points are used, the higher the resolution in the spectrum becomes, but the longer the calculation takes.

Note: If you enter the value manually, any integer value from 3 to 524288 is available. Remote command:

[SENSe:]IQ:FFT:LENGth on page 195

Window Function ← Advanced FFT mode / Basic Settings

In the I/Q analyzer you can select one of several FFT window types. The following window types are available:

●

Blackman-Harris

●

Flattop

●

Gauss

●

Rectangular

●

5-Term

Remote command:

[SENSe:]IQ:FFT:WINDow:TYPE on page 195

Window Overlap ← Advanced FFT mode / Basic Settings

Defines the part of a single FFT window that is re-calculated by the next FFT calculation when using multiple FFT windows.

Remote command:

[SENSe:]IQ:FFT:WINDow:OVERlap on page 195

Window Length ← Advanced FFT mode / Basic Settings

Defines the number of samples to be included in a single FFT window in averaging mode. (In single mode, the window length corresponds to the " Record Length " on page 79.)

However, the window length may not be longer than the FFT Length .

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Remote command:

[SENSe:]IQ:FFT:WINDow:LENGth on page 195

5.7.2 Sweep Settings

Access: "Overview" > "Bandwidth" > "Sweep" tab

Configuration

Data Acquisition and Bandwidth Settings

Sweep Points................................................................................................................ 82

Sweep/Average Count ................................................................................................. 83

Continuous Sweep / Run Cont .....................................................................................83

Single Sweep / Run Single ...........................................................................................83

Continue Single Sweep ................................................................................................84

Select Frame.................................................................................................................84

Continue Frame ........................................................................................................... 84

Frame Count ................................................................................................................ 85

Clear Spectrogram .......................................................................................................85

Sweep Points

In the I/Q Analyzer application, a specific frequency bandwidth is swept for a specified measurement time. During this time, a defined number of samples (= "Record Length" ) are captured. These samples are then evaluated by the applications. Therefore, in this case the number of sweep points does not define the amount of data to be acquired, but rather the number of trace points that are evaluated and displayed in the result diagrams.

Note: As opposed to previous versions of the I/Q Analyzer, the sweep settings are now window-specific. For some result displays, the sweep points may not be editable as they are determined automatically, or restrictions may apply. For the I/Q vector result display, the number of I/Q samples to record ( "Record Length" ) must be identical to the number of trace points to be displayed ("Sweep Points"). Thus, the sweep points are not editable for this result display. If the "Record Length" is edited, the sweep points are adapted automatically. For record lengths outside the valid range of sweep points, i.e. less than 101 points or more than 100001 points, the diagram does not show valid results.

Using fewer than 4096 sweep points with a detector other than "Auto Peak" may lead to wrong level results. For details see "Combining results - trace detector" on page 40.

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Remote command:

[SENSe:]SWEep[:WINDow<n>]:POINts on page 215

Sweep/Average Count

Defines the number of sweeps to be performed in the single sweep mode. Values from 0 to 200000 are allowed. If the values 0 or 1 are set, one sweep is performed.

The sweep count is applied to all the traces in all diagrams. If the trace modes "Average" , "Max Hold" or "Min Hold" are set, this value also deter-

mines the number of averaging or maximum search procedures. In continuous sweep mode, if "Sweep Count" = 0 (default), averaging is performed

over 10 sweeps. For "Sweep Count" =1, no averaging, maxhold or minhold operations are performed.

Remote command:

[SENSe:]SWEep:COUNt on page 214

Continuous Sweep / Run Cont

After triggering, starts the sweep and repeats it continuously until stopped. This is the default setting.

After triggering, starts the measurement and repeats it continuously until stopped. While the measurement is running, the "Continuous Sweep" softkey and the [RUN

CONT] key are highlighted. The running measurement can be aborted by selecting the highlighted softkey or key again. The results are not deleted until a new measurement is started.

Note: Sequencer. If the Sequencer is active, the "Continuous Sweep" softkey only controls the sweep mode for the currently selected channel. However, the sweep mode only takes effect the next time the Sequencer activates that channel, and only for a channel-defined sequence. In this case, a channel in continuous sweep mode is swept repeatedly. If the Sequencer is active in MSRT mode, the "Continuous Sweep" function does not start data capturing. It merely affects trace averaging over multiple sequences. In this case, trace averaging is performed.

Furthermore, the [RUN CONT] key controls the Sequencer, not individual sweeps. [RUN CONT] starts the Sequencer in continuous mode.

Remote command:

INITiate<n>:CONTinuous on page 212

Configuration

Data Acquisition and Bandwidth Settings

Single Sweep / Run Single

After triggering, starts the number of sweeps set in "Sweep Count". The measurement stops after the defined number of sweeps has been performed.

While the measurement is running, the "Single Sweep" softkey and the [RUN SINGLE] key are highlighted. The running measurement can be aborted by selecting the highlighted softkey or key again.

Note: Sequencer. If the Sequencer is active, the "Single Sweep" softkey only controls the sweep mode for the currently selected channel. However, the sweep mode only takes effect the next time the Sequencer activates that channel, and only for a chan-

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nel-defined sequence. In this case, the Sequencer sweeps a channel in single sweep mode only once. Furthermore, the [RUN SINGLE] key controls the Sequencer, not individual sweeps. [RUN SINGLE] starts the Sequencer in single mode.

If the Sequencer is off, only the evaluation for the currently displayed channel is updated.

For details on the Sequencer, see the R&S FSV/A User Manual. Remote command:

INITiate<n>[:IMMediate] on page 213

Continue Single Sweep

After triggering, repeats the number of sweeps set in "Sweep Count", without deleting the trace of the last measurement.

While the measurement is running, the "Continue Single Sweep" softkey and the [RUN SINGLE] key are highlighted. The running measurement can be aborted by selecting the highlighted softkey or key again.

Remote command:

INITiate<n>:CONMeas on page 211

Configuration

Data Acquisition and Bandwidth Settings

Select Frame

Selects a specific frame, loads the corresponding trace from the memory, and displays it in the Spectrum window.

Note that activating a marker or changing the position of the active marker automatically selects the frame that belongs to that marker.

This function is only available in single sweep mode or if the sweep is stopped, and only if a spectrogram is selected.

The most recent frame is number 0, all previous frames have a negative number. Remote command:

CALCulate<n>:SPECtrogram:FRAMe:SELect on page 225

Continue Frame

Determines whether the results of the previous sweeps are included in the analysis of the next sweeps for trace modes "Max Hold" , "Min Hold" , and "Average" .

This function is available in single sweep mode only.

●

When the average or peak values are determined for the new sweep, the results of the previous sweeps in the spectrogram are also taken into account.

●

Off

The average or peak values are determined from the results of the newly swept frames only.

Remote command:

CALCulate<n>:SPECtrogram:CONTinuous on page 224

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Frame Count

Determines how many frames are plotted during a single sweep (as opposed to a continuous sweep). The maximum number of possible frames depends on the history depth (see " History Depth " on page 94).

Remote command:

CALCulate<n>:SPECtrogram:FRAMe:COUNt on page 224

Clear Spectrogram

Resets the spectrogram result display and clears the history buffer. This function is only available if a spectrogram is selected. Remote command:

CALCulate<n>:SPECtrogram:CLEar[:IMMediate] on page 224

5.8 Display Configuration

Access: "Overview" > "Display Config"

Configuration

Adjusting Settings Automatically

The captured signal can be displayed using various evaluation methods. All evaluation methods available for the current application are displayed in the evaluation bar in SmartGrid mode.

For a description of the available evaluation methods see Chapter 3, "Measurement

and Result Displays", on page 13.

Up to 6 evaluations can be displayed in the I/Q Analyzer at any time, including several graphical diagrams, marker tables or peak lists.

The selected evaluation method not only affects the result display in a window, but also the results of the trace data query in remote control (see TRACe<n>[:DATA] on page 269).

5.9 Adjusting Settings Automatically

Some settings can be adjusted by the R&S FSV/A automatically according to the current measurement settings. In order to do so, a measurement is performed. The duration of this measurement can be defined automatically or manually.

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Adjusting settings automatically during triggered measurements

When you select an auto adjust function, a measurement is performed to determine the optimal settings. If you select an auto adjust function for a triggered measurement, you are asked how the R&S FSV/A should behave:

●

(default:) The measurement for adjustment waits for the next trigger

●

The measurement for adjustment is performed without waiting for a trigger. The trigger source is temporarily set to "Free Run" . After the measurement is completed, the original trigger source is restored. The trigger level is adjusted as follows:

– For IF Power and RF Power triggers:

Trigger Level = Reference Level - 15 dB

– For Video trigger:

Trigger Level = 85 %

Remote command:

[SENSe:]ADJust:CONFigure:TRIGger on page 202

Configuration

Adjusting Settings Automatically

Adjusting all Determinable Settings Automatically ( Auto All )...................................... 86

Adjusting the Center Frequency Automatically ( Auto Frequency ).............................. 86

Setting the Reference Level Automatically ( Auto Level ).............................................87

Resetting the Automatic Measurement Time ( Meastime Auto )...................................87

Changing the Automatic Measurement Time ( Meastime Manual ).............................. 87

Upper Level Hysteresis ................................................................................................87

Lower Level Hysteresis ................................................................................................88

Adjusting all Determinable Settings Automatically ( Auto All )

Activates all automatic adjustment functions for the current measurement settings. This includes:

●

Auto Frequency

●

Auto Level

Note: Auto measurement. For some measurements, the Adjusting all Determinable

Settings Automatically ( Auto All ) function determines the required measurement

parameters automatically. In this case, the progress of the auto measurement is indicated in a message box. See the R&S FSV3000/ FSVA3000 base unit user manual.

Remote command:

[SENSe:]ADJust:ALL on page 200

Adjusting the Center Frequency Automatically ( Auto Frequency )

The R&S FSV/A adjusts the center frequency automatically. The optimum center frequency is the frequency with the highest S/N ratio in the fre-

quency span. As this function uses the signal counter, it is intended for use with sinusoidal signals.

At the same time, the optimal reference level is also set (see " Setting the Reference

Level Automatically ( Auto Level )" on page 67).

This function is not available for input from the optional Digital Baseband Interface.

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Remote command:

[SENSe:]ADJust:FREQuency on page 202

Setting the Reference Level Automatically ( Auto Level )

To determine the required reference level, a level measurement is performed on the R&S FSV/A.

You can change the measurement time for the level measurement if necessary (see "

Changing the Automatic Measurement Time ( Meastime Manual )" on page 87).

Remote command:

[SENSe:]ADJust:LEVel on page 202

Configuration

Adjusting Settings Automatically

Resetting the Automatic Measurement Time ( Meastime Auto )

Resets the measurement duration for automatic settings to the default value. Remote command:

[SENSe:]ADJust:CONFigure:DURation:MODE on page 201

Changing the Automatic Measurement Time ( Meastime Manual )

This function allows you to change the measurement duration for automatic setting adjustments. Enter the value in seconds.

Note: The maximum possible measurement duration depends on the currently selected measurement and the installed (optional) hardware. Thus, the measurement duration actually used to determine the automatic settings may be shorter than the value you define here.

Remote command:

[SENSe:]ADJust:CONFigure:DURation:MODE on page 201 [SENSe:]ADJust:CONFigure:DURation on page 200

Upper Level Hysteresis

When the reference level is adjusted automatically using the Auto Level function, the internal attenuators and the preamplifier are also adjusted. To avoid frequent adaptation due to small changes in the input signal, you can define a hysteresis. This setting defines an upper threshold the signal must exceed (compared to the last measurement) before the reference level is adapted automatically.

Remote command:

[SENSe:]ADJust:CONFigure:HYSTeresis:UPPer on page 201

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Lower Level Hysteresis

When the reference level is adjusted automatically using the Auto Level function, the internal attenuators and the preamplifier are also adjusted. To avoid frequent adaptation due to small changes in the input signal, you can define a hysteresis. This setting defines a lower threshold the signal must fall below (compared to the last measurement) before the reference level is adapted automatically.

Remote command:

[SENSe:]ADJust:CONFigure:HYSTeresis:LOWer on page 201

Configuration

Adjusting Settings Automatically

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6 Analysis

Access: "Overview" > "Analysis"

General result analysis settings concerning the trace, markers etc. are identical to the analysis functions in the Spectrum application, except for the lines and special marker functions, which are not available for I/Q data.

The remote commands required to perform these tasks are described in Chapter 6,

"Analysis", on page 89.

● Trace Settings.........................................................................................................89

● Spectrogram Settings..............................................................................................93

● Trace / Data Export Configuration...........................................................................97

● Marker Usage........................................................................................................100

6.1 Trace Settings

Analysis

Trace Settings

Access: "Overview" > "Analysis" > "Traces"

Or: [TRACE] > "Trace Config"

You can configure the settings for up to 6 individual traces.

Trace data can also be exported to an ASCII file for further analysis. For details see

Chapter 6.3, "Trace / Data Export Configuration", on page 97.

For I/Q Vector evaluation mode, only 1 trace is available and the detector is not editable.

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Trace 1 / Trace 2 / Trace 3 / Trace 4 / Trace 5 / Trace 6 ..............................................90

Trace Mode ..................................................................................................................90

Detector ........................................................................................................................90

Hold ..............................................................................................................................91

Smoothing ....................................................................................................................91

Average Mode ..............................................................................................................91

Predefined Trace Settings - Quick Config ....................................................................92

Trace 1 / Trace 2 / Trace 3 / Trace 4 (Softkeys)............................................................92

Copy Trace ...................................................................................................................92

Trace 1 / Trace 2 / Trace 3 / Trace 4 / Trace 5 / Trace 6

Selects the corresponding trace for configuration. The currently selected trace is highlighted.

Remote command: Selected via numeric suffix of:TRACe<1...6> commands

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>[:STATe] on page 219

Trace Mode

Defines the update mode for subsequent traces. "Clear/ Write" "Max Hold"

"Min Hold"

"Average"

"View" "Blank" Remote command:

DISPlay[:WINDow<n>]:TRACe<t>:MODE on page 217

Analysis

Trace Settings

Overwrite mode (default): the trace is overwritten by each sweep. The maximum value is determined over several sweeps and dis-

played. The R&S FSV/A saves each trace point in the trace memory only if the new value is greater than the previous one.

The minimum value is determined from several measurements and displayed. The R&S FSV/A saves each trace point in the trace memory only if the new value is lower than the previous one.

The average is formed over several sweeps. The Sweep/Average Count determines the number of averaging procedures.

The current contents of the trace memory are frozen and displayed. Removes the selected trace from the display.

Detector

Defines the trace detector to be used for trace analysis. The trace detector is used to combine multiple FFT window results to create the final

spectrum. (Note: in previous versions of the R&S FSV/A, the I/Q Analyzer always used the linear average detector.) If necessary, the trace detector is also used to reduce the number of calculated frequency points (defined by the FFT length) to the defined number of sweep points. By default, the Autopeak trace detector is used.

"Auto"

"Type"

Selects the optimum detector for the selected trace and filter mode. This is the default setting.

Defines the selected detector type.

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Remote command:

[SENSe:][WINDow<n>:]DETector<t>[:FUNCtion] on page 221 [SENSe:][WINDow<n>:]DETector<t>[:FUNCtion]:AUTO on page 221

Hold

If activated, traces in "Min Hold" , "Max Hold" and "Average" mode are not reset after specific parameter changes have been made.

Normally, the measurement is started again after parameter changes, before the measurement results are analyzed (e.g. using a marker). In all cases that require a new measurement after parameter changes, the trace is reset automatically to avoid false results (e.g. with span changes). For applications that require no reset after parameter changes, the automatic reset can be switched off.

The default setting is off. Remote command:

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:MODE:HCONtinuous

on page 218

Smoothing

If enabled, the trace is smoothed by the specified value (between 1 % and 50 %). The smoothing value is defined as a percentage of the display width. The larger the smoothing value, the greater the smoothing effect.

For more information see the R&S FSV/A User Manual.

Analysis

Trace Settings

Remote command:

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:SMOothing[:STATe]

on page 220

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>:SMOothing:APERture

on page 220

Average Mode

Defines the mode with which the trace is averaged over several sweeps. This setting is generally applicable if trace mode "Average" is selected. For FFT

sweeps, the setting also affects the VBW (regardless of whether or not the trace is averaged).

(See the chapter on ACLR power measurements in the R&S FSV/A User Manual.) How many sweeps are averaged is defined by the " Sweep/Average Count "

on page 83. "Linear"

"Logarithmic"

The power level values are converted into linear units prior to averaging. After the averaging, the data is converted back into its original unit.

For logarithmic scaling, the values are averaged in dBm. For linear scaling, the behavior is the same as with linear averaging.

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Analysis

Trace Settings

"Power"

Activates linear power averaging. The power level values are converted into unit Watt prior to averaging. After the averaging, the data is converted back into its original unit. Use this mode to average power values in Volts or Amperes correctly. In particular, for small VBW values (smaller than the RBW), use power averaging mode for correct power measurements in FFT sweep mode.

Remote command:

[SENSe:]AVERage<n>:TYPE on page 220

Predefined Trace Settings - Quick Config

Commonly required trace settings have been predefined and can be applied very quickly by selecting the appropriate button.

Function Trace Settings

Preset All Traces Trace 1: Clear Write

Traces 2-6: Blank

Set Trace Mode Max | Avg | Min

Trace 1: Max Hold

Trace 2: Average

Trace 3: Min Hold

Traces 4-6: Blank

Set Trace Mode Max | ClrWrite | Min

Trace 1: Max Hold

Trace 2: Clear Write

Trace 3: Min Hold

Traces 4-6: Blank

Trace 1 / Trace 2 / Trace 3 / Trace 4 (Softkeys)

Displays the "Traces" settings and focuses the "Mode" list for the selected trace. Remote command:

DISPlay[:WINDow<n>][:SUBWindow<w>]:TRACe<t>[:STATe] on page 219

Copy Trace Access: "Overview" > "Analysis" > "Traces" > "Copy Trace"

Copies trace data to another trace. The first group of buttons (labeled "Trace 1" to "Trace 6" ) selects the source trace. The

second group of buttons (labeled "Copy to Trace 1" to "Copy to Tace 6" ) selects the destination.

Remote command:

TRACe<n>:COPY on page 222

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6.2 Spectrogram Settings

Access: [TRACE] > "Spectrogram Config"

The individual settings available for spectrogram display are described here. For settings on color mapping, see Chapter 6.2.2, "Color Map Settings", on page 96.

Settings concerning the frames and how they are handled during a sweep are provided as additional sweep settings for spectrogram display.

See Chapter 5.7.2, "Sweep Settings", on page 82.

Search functions for spectrogram markers are described in Chapter 6.4.2.2, "Marker

Search Settings for Spectrograms", on page 109.

● General Spectrogram Settings................................................................................93

● Color Map Settings..................................................................................................96

6.2.1 General Spectrogram Settings

Analysis

Spectrogram Settings

Access: [TRACE] > "Spectrogram Config"

This section describes general settings for spectrogram display.

State..............................................................................................................................94

3D Spectrogram State...................................................................................................94

Select Frame.................................................................................................................94

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History Depth ............................................................................................................... 94

3-D Display Depth.........................................................................................................94

Time Stamp ..................................................................................................................95

Color Mapping ..............................................................................................................95

Continuous Sweep / Run Cont .....................................................................................95

Single Sweep / Run Single ...........................................................................................95

Clear Spectrogram .......................................................................................................96

State

Activates and deactivates a Spectrogram subwindow. "Off" Remote command:

CALCulate<n>:SPECtrogram:LAYout on page 226

3D Spectrogram State

Activates and deactivates a 3-dimensional spectrogram. As opposed to the common 2dimensional spectrogram, the power is not only indicated by a color mapping, but also in a third dimension, the z-axis.

For details see the R&S FSV/A User Manual.

Analysis

Spectrogram Settings

Closes the Spectrogram subwindow.

Remote command:

CALCulate<n>:SPECtrogram:THReedim[:STATe] on page 226

Select Frame

Selects a specific frame, loads the corresponding trace from the memory, and displays it in the Spectrum window.

Note that activating a marker or changing the position of the active marker automatically selects the frame that belongs to that marker.

This function is only available in single sweep mode or if the sweep is stopped, and only if a spectrogram is selected.

The most recent frame is number 0, all previous frames have a negative number. Remote command:

CALCulate<n>:SPECtrogram:FRAMe:SELect on page 225

History Depth

Sets the number of frames that the R&S FSV/A stores in its memory. The maximum number of frames depends on the "Sweep Points" on page 82. For an overview of the maximum number of frames depending on the number of

sweep points, see the R&S FSV/A User Manual. If the memory is full, the R&S FSV/A deletes the oldest frames stored in the memory

and replaces them with the new data. Remote command:

CALCulate<n>:SPECtrogram:HDEPth on page 225

3-D Display Depth

Defines the number of frames displayed in a 3-dimensional spectrogram.

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For details see the R&S FSV/A User Manual.

Time Stamp

Activates and deactivates the timestamp. The timestamp shows the system time while the measurement is running. In single sweep mode or if the sweep is stopped, the timestamp shows the time and date of the end of the sweep.

When active, the timestamp replaces the display of the frame number. Remote command:

CALCulate<n>:SPECtrogram:TSTamp[:STATe] on page 228 CALCulate<n>:SPECtrogram:TSTamp:DATA? on page 227

Color Mapping

Opens the "Color Mapping" dialog. For details see the R&S FSV/A User Manual.

Continuous Sweep / Run Cont

After triggering, starts the sweep and repeats it continuously until stopped. This is the default setting.

After triggering, starts the measurement and repeats it continuously until stopped. While the measurement is running, the "Continuous Sweep" softkey and the [RUN

CONT] key are highlighted. The running measurement can be aborted by selecting the highlighted softkey or key again. The results are not deleted until a new measurement is started.

Furthermore, the [RUN CONT] key controls the Sequencer, not individual sweeps. [RUN CONT] starts the Sequencer in continuous mode.

Remote command:

INITiate<n>:CONTinuous on page 212

Analysis

Spectrogram Settings

Single Sweep / Run Single

After triggering, starts the number of sweeps set in "Sweep Count". The measurement stops after the defined number of sweeps has been performed.

While the measurement is running, the "Single Sweep" softkey and the [RUN SINGLE] key are highlighted. The running measurement can be aborted by selecting the highlighted softkey or key again.

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Furthermore, the [RUN SINGLE] key controls the Sequencer, not individual sweeps. [RUN SINGLE] starts the Sequencer in single mode.

If the Sequencer is off, only the evaluation for the currently displayed channel is updated.

For details on the Sequencer, see the R&S FSV/A User Manual. Remote command:

INITiate<n>[:IMMediate] on page 213

Clear Spectrogram

Resets the spectrogram result display and clears the history buffer. This function is only available if a spectrogram is selected. Remote command:

CALCulate<n>:SPECtrogram:CLEar[:IMMediate] on page 224

6.2.2 Color Map Settings

Analysis

Spectrogram Settings

Access: "Overview" > "Analysis" > "Traces" > "Spectrogram" > "Color Mapping"

or: [TRACE] > "Spectrogram Config" > "Color Mapping"

In addition to the available color settings, the dialog box displays the current color map and provides a preview of the display with the current settings.

Figure 6-1: Color Mapping dialog box

1 = Color map: shows the current color distribution 2 = Preview pane: shows a preview of the spectrogram with any changes that you make to the color

scheme 3 = Color curve pane: graphical representation of all settings available to customize the color scheme 4/5 = Color range start and stop sliders: define the range of the color map or amplitudes for the spectrogram

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6 = Color curve slider: adjusts the focus of the color curve 7 = Histogram: shows the distribution of measured values 8 = Scale of the horizontal axis (value range)

Start / Stop ................................................................................................................... 97

Shape ...........................................................................................................................97

Hot / Cold / Radar / Grayscale ..................................................................................... 97

Auto ..............................................................................................................................97

Set to Default ............................................................................................................... 97

Close.............................................................................................................................97

Start / Stop

Defines the lower and upper boundaries of the value range of the spectrogram. Remote command:

DISPlay[:WINDow<n>]:SPECtrogram:COLor:LOWer on page 228 DISPlay[:WINDow<n>]:SPECtrogram:COLor:UPPer on page 229

Shape

Defines the shape and focus of the color curve for the spectrogram result display. "-1 to <0" "0" ">0 to 1" Remote command:

DISPlay[:WINDow<n>]:SPECtrogram:COLor:SHAPe on page 229

Analysis

Trace / Data Export Configuration

More colors are distributed among the lower values Colors are distributed linearly among the values More colors are distributed among the higher values

Hot / Cold / Radar / Grayscale

Sets the color scheme for the spectrogram. Remote command:

DISPlay[:WINDow<n>]:SPECtrogram:COLor[:STYLe] on page 230

Auto

Defines the color range automatically according to the existing measured values for optimized display.

Set to Default

Sets the color mapping to the default settings. Remote command:

DISPlay[:WINDow<n>]:SPECtrogram:COLor:DEFault on page 228

Saves the changes and closes the dialog box.

6.3 Trace / Data Export Configuration

Access: "Save" > "Export" > "Trace Export Configuration"

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Or: [TRACE] > "Trace Config" > "Trace / Data Export"

The R&S FSV/A provides various evaluation methods for the results of the performed measurements. However, you may want to evaluate the data with other, external applications. In this case, you can export the measurement data to an ASCII file.

The standard data management functions (e.g. saving or loading instrument settings) that are available for all R&S FSV/A applications are not described here.

Analysis

Trace / Data Export Configuration

Export all Traces and all Table Results ........................................................................ 98

Include Instrument & Measurement Settings ............................................................... 98

Trace to Export .............................................................................................................99

Decimal Separator ....................................................................................................... 99

Export Trace to ASCII File ............................................................................................99

└ File Type ...................................................................................................... 100

└ Decimal Separator ....................................................................................... 100

Export Spectrogram to ASCII File ..............................................................................100

Export all Traces and all Table Results

Selects all displayed traces and result tables (e.g. Result Summary, marker table etc.) in the current application for export to an ASCII file.

Alternatively, you can select one specific trace only for export (see Trace to Export ). The results are output in the same order as they are displayed on the screen: window

by window, trace by trace, and table row by table row. Remote command:

FORMat:DEXPort:TRACes on page 272

Include Instrument & Measurement Settings

Includes additional instrument and measurement settings in the header of the export file for result data.

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Remote command:

FORMat:DEXPort:HEADer on page 272

Trace to Export

Defines an individual trace to be exported to a file. This setting is not available if Export all Traces and all Table Results is selected.

Decimal Separator

Defines the decimal separator for floating-point numerals for the data export/import files. Evaluation programs require different separators in different languages.

Remote command:

FORMat:DEXPort:DSEParator on page 271

Export Trace to ASCII File

Saves the selected trace or all traces in the currently active result display to the specified file and directory in the selected ASCII format.

Analysis

Trace / Data Export Configuration

Note: Secure user mode.

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In secure user mode, settings that are stored on the instrument are stored to volatile memory, which is restricted to 256 MB. Thus, a "memory limit reached" error can occur although the hard disk indicates that storage space is still available.

To store data permanently, select an external storage location such as a USB memory device.

For details, see "Protecting Data Using the Secure User Mode" in the "Data Management" section of the R&S FSV3000/ FSVA3000 base unit user manual.

Remote command:

MMEMory:STORe<n>:TRACe on page 273

File Type ← Export Trace to ASCII File

Determines the format of the ASCII file to be imported or exported. Depending on the external program in which the data file was created or is evaluated,

a comma-separated list (CSV) or a plain data format (DAT) file is required. Remote command:

FORMat:DEXPort:FORMat on page 271

Analysis

Marker Usage

Decimal Separator ← Export Trace to ASCII File

Defines the decimal separator for floating-point numerals for the data export/import files. Evaluation programs require different separators in different languages.

Remote command:

FORMat:DEXPort:DSEParator on page 271

Export Spectrogram to ASCII File

Opens a file selection dialog box and saves the selected spectrogram in ASCII format (.dat) to the specified file and directory.

If the spectrogram display is selected when you perform this function, the entire histogram buffer with all frames is exported to a file. The data corresponding to a particular frame begins with information about the frame number and the time that frame was recorded. For large history buffers the export operation can take some time.

For details on the file format, see the R&S FSV3000/ FSVA3000 base unit user manual.

Remote command:

MMEMory:STORe<n>:SPECtrogram on page 272

6.4 Marker Usage

Access: "Overview" > "Analysis"

The following marker settings and functions are available in the I/Q Analyzer application.

For "I/Q-Vector" displays markers are not available.

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Specifications and Main Features

Frequently Asked Questions

User Manual

Contents

1 Preface

1.1 Documentation Overview

1.1.1 Getting Started Manual

1.1.2 User Manuals and Help

1.1.3 Service Manual

1.1.4 Instrument Security Procedures

1.1.5 Basic Safety Instructions

1.1.6 Data Sheets and Brochures

1.1.7 Release Notes and Open Source Acknowledgment (OSA)

1.1.8 Application Notes, Application Cards, White Papers, etc.

1.2 About this Manual

1.3 Conventions Used in the Documentation

1.3.1 Typographical Conventions

1.3.2 Conventions for Procedure Descriptions

1.3.3 Notes on Screenshots

2 Welcome to the I/Q Analyzer Application

2.1 Starting the I/Q Analyzer Application

2.2 Understanding the Display Information

3 Measurement and Result Displays

Basics on I/Q Data Acquisition and Processing

4.1 Processing Analog I/Q Data from RF Input

4.1.1 Sample Rate and Maximum Usable I/Q Bandwidth for RF Input

4.1.1.1 Bandwidth Extension Options

4.1.1.2 Relationship Between Sample Rate, Record Length and Usable I/Q Bandwidth

4.1.1.3 R&S FSV/A Without Additional Bandwidth Extension Options

4.1.1.4 R&S FSV/A with I/Q Bandwidth Extension Option B40 or U40

4.1.1.5 R&S FSV/A with I/Q Bandwidth Extension Option B200 or U200

4.1.1.6 R&S FSV/A with I/Q Bandwidth Extension Option B400 or U400

4.2 Using Probes

4.2.1 RF Probes

4.2.1.1 MultiMode Function and Offset Compensation for Modular RF Probes

4.3 Basics on External Generator Control

4.3.1 External Generator Connections

4.3.2 Overview of Supported Generators

4.3.3 Generator Setup Files

4.3.4 Calibration Mechanism

4.3.5 Normalization

4.3.6 Reference Trace, Reference Line and Reference Level

4.3.7 Coupling the Frequencies

4.3.8 Displayed Information and Errors

4.4 Basics on Input from I/Q Data Files

4.5 IF and Video Signal Output

4.6 Receiving and Providing Trigger Signals

4.7 I/Q Data Import and Export

4.8 Basics on FFT

4.8.1 Window Functions

4.8.2 Overlapping

4.8.3 Dependencies Between FFT Parameters

4.8.4 Frequency Resolution of FFT Results - RBW

4.8.5 FFT Calculation Methods

5 Configuration

5.1 Configuration Overview

5.2 Import/Export Functions

5.3 Data Input and Output Settings

5.3.1 Input Source Settings

5.3.1.1 Radio Frequency Input

5.3.1.2 Settings for Input from I/Q Data Files

5.3.1.3 Probe Settings

5.3.1.4 External Generator Control Settings

Interface Configuration Settings

Measurement Settings

Source Calibration Functions

5.3.2 Output Settings

5.4 Amplitude

5.4.1 Amplitude Settings

5.4.2 Scaling the Y-Axis

5.5 Frequency Settings

5.6 Trigger Settings

5.7 Data Acquisition and Bandwidth Settings

5.7.1 Data Acquisition

5.7.2 Sweep Settings

5.8 Display Configuration

5.9 Adjusting Settings Automatically

6 Analysis

6.1 Trace Settings