340 Results
Differential measurements with Spectrum Analyzers and Probes
28-Jun-2013 | AN-No. 1EF84
With R&S®FE170 frontends, Rohde & Schwarz introduces innovative up- and down- frequency converters, providing both high performance and a simple setup with R&S®SMW200A signal generators and R&S®FSW signal and spectrum analyzers. No additional external sources are required, with all devices automatically recognized and all necessary calibration data transferred automatically.
Digital pre-distortion (DPD) is a common method. This article describes an approach to generate a pre-distorted signal based on a hard-clipper.
13-Sep-2017 | AN-No. 1EF99
The application note address test and measurement possibilities for DVB-S2 and DVB-S2X signals in the Ku & Ka -band.
08-Mar-2016 | AN-No. 1MA273
The document focusses on devices for the 3.5 GHz NR (5G New Radio) candidate band, but its findings are equally applicable to developments and measurements for K-band satellite applications or mmW NR candidate bands,
01-Aug-2017 | AN-No. 1MA289
This application note describes how all required receiver (Rx) tests (TS25.141 Chapter 7) can be performed easily and quickly by using vector signal generators and CW sources from Rohde & Schwarz.
21-Oct-2014 | AN-No. 1MA114
Hints and Tricks for Remote Control of Spectrum and Network Analyzers
19-Aug-2014 | AN-No. 1EF62
This Application Note addresses signal measurements and analysis of automotive radars that are crucial during the development and verification stages.
10-Jun-2016 | AN-No. 1MA267
Together with R&S®FE170 frontends as up- and down- frequency converters, and an R&S®FSW signal and spectrum analyzer, this video demonstrates how to generate, transmit over the air, and analyze a 4 GHz bandwidth single carrier signal with 16QAM modulation at 148 GHz.
LTE is under continuous development. Release 10 (LTE-Advanced) introduced carrier aggregation (CA) as the primary enhancement. Releases 11 and 12 add several new components to LTE. Some are enhancements to existing features (such as improvements to CA), while others are completely new concepts, such as coordinated multipoint (CoMP).This application note summarizes the Rohde & Schwarz test solutions for LTE-Advanced according to Releases 11 and 12 using vector signal generators, signal and spectrum analyzers and the wideband radio communication tester.
14-Jul-2016 | AN-No. 1MA272
Direct remote control of OSP via VNA and SA
06-Dec-2013 | AN-No. 1MA226
conducted conformance testing according to TS 38.141-1, Rel. 15
This application note describes how all mandatory RF receiver tests can be performed quickly and conveniently with signal generators from Rohde & Schwarz.
02-Dec-2020 | AN-No. GFM314
R&S®Fxx-K40 Phase Noise Measurement Application – R&S®FSW-K40, R&S®FSMR3-K40, R&S®FSV3-K40, R&S®FPS-K40, R&S®FSV-K40, R&S®FPL1-K40 - Specifications
This application note describes the configuration of a Miracast wireless video transmission system and how to measure delay times.
01-Oct-2015 | AN-No. 1MA250
conducted conformance testing according to TS 38.141-1, Rel. 16
This application note describes how all mandatory RF transmitter tests according to Release 16, can be performed with signal or spectrum analyzers from Rohde & Schwarz.
27-Jan-2021 | AN-No. GFM313
radiated conformance testing according to TS 38.141-2, Rel. 16
3GPP defines the Radio Frequency (RF) conformance test methods and requirements for 5G NR Base Stations (BS) in the technical specifications TS 38.141.
30-Jun-2020 | AN-No. GFM325
R&S®VSE-K60(x) / FSW-K60(x) / FSWP-K60(x) / FSV3-K60(x) Transient measurements - Specifications
1MA210 - Testing LTE Release 9 Features. This Application Note describes the T&M methods for LTE Release 9 features using Rohde & Schwarz instruments.
26-Apr-2013 | AN-No. 1MA210
09-Nov-2020
Rohde & Schwarz helps to protect Dutch soldiers in the fieldRohde & Schwarz Benelux to provide signal and spectrum analyzing and recording solutions for the Netherlands’ Defence Material Organization TESLA-M project.
This application note summarizes the Rohde &Schwarz test solutions for LTE-Advanced (Release 10) using Vector Signal Generators, Signal and Spectrum Analyzers and the Wideband Radio Communication Tester.
03-Sep-2014 | AN-No. 1MA166
Introduction to Attribute Based Instrument Drivers
01-Dec-2012 | AN-No. 1MA170
This application note aims to explain test procedures and characterization of the relevant parameters for active phased array antennas.
04-Jul-2016 | AN-No. 1MA248
Noise Power Ratio Signal Generation and Measurement
Noise Power Ratio is a tool for WinIQSIM™ to generate noise power ratio stimulus signals and measure the resulting noise power ratio of a device.
06-Nov-2015 | AN-No. 1MA29
Assisting Tools for Operation of Windows-Based T&M Instruments
13-Jun-2013 | AN-No. 1MA218
06-Sep-2022
From gigahertz to terahertz, Rohde & Schwarz exhibits latest mmWave test solutions at EuMW 2022 in MilanRohde & Schwarz will showcase at EuMW in Milan the latest testing capabilities for microwave components and new solutions for the road to 6G.
This application note describes how all required transmitter (Tx) tests can be performed quickly and easily by using signal and spectrum analyzers.
11-May-2016 | AN-No. 1MA154
Amplifier measurements with Rohde & Schwarz spectrum analyzers Flyer
17-Aug-2022
VIAVI and Rohde & Schwarz support Auray OTIC in awarding O-RAN conformance certification for international marketsThe Auray O-RAN Testing and Integration Centre (OTIC) and Security Lab provides test, validation and integration services to a supply chain of open radio access network vendors. In their first successful certification of an O-RAN radio unit (O-RU) according to O-RAN ALLIANCE as part of the O-RAN Certification and Badging Program, Auray OTIC relied on the integrated solution for O-RU conformance testing by Rohde & Schwarz and VIAVI.
27-Nov-2018
DOCOMO and Rohde & Schwarz cooperate in pioneering beyond 5G with frequency bands up to 150 GHzNTT DOCOMO INC. and Rohde & Schwarz have joined forces set up the world's first ultra-wideband channel sounder for mobile communications exceeding 100 GHz. They conducted radio wave propagation experiments at frequencies up to 150 GHz. The frequency bands from 100 GHz to 300 GHz are expected to enable further high-speed and large-capacity communication for the next generation beyond 5G.