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Learn how to configure Rohde & Schwarz products to fit your application. Search our database by product, technology, or application to find relevant technical documents.
Search Application Notes & Cards
Learn how to configure Rohde & Schwarz products to fit your application. Search our database by product, technology, or application to find relevant technical documents.
82 Results
The application note address test and measurement possibilities for DVB-S2 and DVB-S2X signals in the Ku & Ka -band. The AN includes detailed description of measurement setups, DVB-S2 and DVB-S2X signal generation, up-conversion and signal quality (Error Vector Magnitude and Modulation Error Ratio) analysis in the Ku & Ka-band using Rohde & Schwarz instruments.This paper is intended towards satellite equipment manufacturers, network operators, government & authorities, CE receiver chip set manufacturers, car manufacturer and automotive infotainment system manufactures.
08-Mar-2016 | AN-No. 1MA273
Widespread adoption of higher order modulation schemes, larger signal bandwidths and higher operating frequencies, to enable higher data throughput in communication links like 5G, places increasingly tough demands on the frontend. Signal fidelity is often enhanced with linearization.The greater number of RF chains and signal bandwidth in 5G Frontends mean that DPD (Digital Pre-Distortion) may no longer be the default linearization choice; 5G Frontends will be completely different from their 4G predecessors.The key metrics of Efficiency, Linearity, Bandwidth and Output Power remain, as does the question of how to optimally create the signal with just enough fidelity and power, with a minimum of wasted power. The solution set to that question, however, has never been greater.Amongst other topics, this White Paper, (i) proposes a classification of Linearization schemes, (ii) introduces the hard limiter, (iii) illustrates linearization of an exemplary mmWave PA using non-DPD techniques, and (iv) introduces a class of linearized transmitters that create their signal and linearity from efficiently generated components.
25-Feb-2016 | AN-No. 1MA269
The application note guides developers and manufactures of Sigfox Devices to perform the required and recommended measurements with test solutions from Rohde & Schwarz. The note will help bring ultranarrowband IoT devices and applications using Sigfox technology to the market as fast as possible and help ensure the desired quality and performance.For R&D, Pre-certification and QA, all currently defined Uplink- and Downlink- measurements are shown using the compact R&S®FPL1000 Spectrum Analyzer and R&S®SMBV100A Vector Signal Generator.For Production, use of the R&S®CMW100A Communications Manufacturing Test Set is shown for the most essential Uplink RF tests on Sigfox Devices.Python scripts for giving example SCPI commands demonstrate how measurements shown in manual use can easily be automated.
15-Nov-2017 | AN-No. 1MA294
Signal Generation and Analysis
This Application Note supplements the video series, describing signal generation and signal analysis for Dynamic Spectrum Sharing (DSS) for LTE and 5G NR. The video series is located below this paragraph.In this illustration, a four frame (40 subframes) long LTE sequence will be created, and exemplary MBSFN slots inserted, carrying 5G payloads. That signal sequence will be compiled and played by the SMW signal generator. The FSW signal analyzer LTE and 5G NR personalities are then used to analyze and verify the content of each subframe/slot.Three methods are presented, (1) Manual Entry using the GUI, (2) SCPI command sequence/remote control and (3) configuration file. The latter variants require the download of various files, available at the bottom.The configuration file approach offers the fastest time to initially setup. The SCPI command sequences provides some insight of the functionality and settings at each step, and the supplied MATLAB® script (only core license required) provides a prototype to illustrate the programming of successive slots or subframes. The Manual Entry approach, using the instrument's front panel GUI, provides a step-by-step set-up instruction, which can itself be augmented with SCPI recording, for easy modification and programming.MATLAB® is a registered trademark of The Mathworks, Inc.
30-Mar-2020 | AN-No. GFM337
Propagation measurements are indispensable in the planning of digital, cellular mobile radio net-works. To find the optimum sites for the base stations, a mobile test transmitter system simulating the base station is operated from a number of possible locations. The test receiver system is accommodated in a vehicle, which is driven along a test route to perform measurements. The parameters measured, such as level, bit error rate or channel impulse response, provide information on the coverage within the cell. The main problem is to minimize interference caused by multipath propagation in the reception area. The SME offered by Rohde & Schwarz is a universal test generator that can be used as the core of a test transmitter system. The SME generates the GMSK-modulated signals required for GSM propagation measurements in line with the rele-vant standards. Thanks to its low weight of 17 kg it can be carried even to remote sites. Fitted with the new optional DM Memory Extension (SME-B12, in the following referred to as XMEM), the SME is able to store data sequences of up to 8 Mbit which are long enough for receiver measurements with test mobile stations. A suitable test receiver system is for instance a test mobile station for measuring level and bit error rate and the Impulse Response Analyzer PCS from Rohde & Schwarz for measuring the channel impulse response. The present Application Note describes how the XMEM can be loaded with suitable data (test sequence) by the GSM Radiocommunication Test Set CRTP from Rohde & Schwarz and how the SME has to be adjusted for GMSK modulation of these data. First, however, an overview is given of all functions of the XMEM and their operation supplementary to the Operating Manual. Finally, it is explained how the XMEM data can be transferred between PC and SME via the IEEE-488 or RS-232 interface.
01-Jul-1999 | AN-No. 1GPAN14
The Rohde & Schwarz SFU supports several modes of level setting. This Application Note describes the differences between these modes and especially describes a method to achieve a seamless transition without any impact to the output signal during a change of settings on an Rohde & Schwarz SFU (Firmware version > 1.30).
23-Jun-2006 | AN-No. 7BM54
This application note shows how to configure the R&S®AdVISE visual inspection software to automate the immunity testing in line with EN 55020 and CISPR 35 on TV sets and monitors.
30-Jul-2020 | AN-No. 1S007
A measurement campaign quantifying the impact of intermodulation in 5G TDD networks
Critical infrastructure: With the deployment of TDD networks, the mobile network community recognizes the critical importance of cell synchronization and the use of uniform TDD patterns across different networks for the proper operation of mobile radio networks. Variety of scenarios: Possible scenarios include cross-border situations, interactions between private campus networks and public mobile networks, and accidental synchronization chain breaks or misconfigurations within the mobile network.Measurement techniques: To quantify the effects of non-synchronized cells and using different TDD pattern in neighboring networks, R&S, in collaboration with TU Dresden and Advancing Individual Networks GmbH (AIN), conducted a measurement campaign using movable networks with full control over all network parameters. This campaign measured the effects on uplink and downlink throughput, mapping these to RSSI/RSRP values received at the interfered site.Customer benefits: The available quantification is valuable for predicting and assessing potential interference scenarios before setting up and operating a new cell site.
11-Sep-2024 | AN-No. 8NT18
This application note describes how to remotely control the R&S SGMA RF sources SGT100A and SGS100A with a special focus on their high-speed remote control capabilities via LAN based FAST Socket or FAST PCI Express (PCIe) connections which allow round trip setting times of only 100μs.It therefore provides a brief introduction into the general remote control capabilities, explains the interaction of the different SW protocol layers and drivers, and in detail describes how to establish a high-speed remote control connection. Finally, a comparison of the measured setting time performance of the different remote control approaches is provided.
12-May-2016 | AN-No. 1GP107
Power converter and inverter designs for higher power levels are usually based on hard switching half bridge configurations. In such setups, users must pay particular attention to proper switching operations to prevent shoot-through events. Setting up complex real-time trigger conditions using the R&S®RTE and R&S®RTO oscilloscopes increases the test coverage and robustness of converter and inverter systems.
10-Aug-2020
The combination of an SMIQ Signal Generator and an FSE / FSIQ Analyzer enables the most important transmitter and receiver tests on ICO user terminals in quality management and development. This application note presents a series of quick tests in unsynchronized, non-signalling mode. To facilitate integration of SMIQ and FSE / FSIQ into existing test systems, complex instrument settings are supplied as sets of IEC/IEEE-bus commands. Sample files with burst data for uplink and downlink signals allow the configuration, execution and optimization of the tests described, even without a DUT.
08-May-2000 | AN-No. 1MA23
This application note describes three ways of generating multicarrier signals with high dynamic range for testing power amplifiers of 3GPP radio base stations. The corresponding sets of waveform (*.wv) files are delivered with this application note. The WinIQSIM™ software is used to download these files to the signal generator(s).Tips for optimizing spectrum analyzer settings in order to measure the Adjacent Channel Leakage Ratio (ACLR) are given.
17-Feb-2005 | AN-No. 1MA48
Rohde & Schwarz test receivers of the ESXS, ESS and ESXN series are equipped with a 3.5' floppy-disk drive so that receiver settings, scan results, limit lines, transducer factors and whole sets of transducers can be stored on a floppy disk and reloaded into the receiver. Data can only be loaded into the receiver type from which they have been stored. The reason is that data eg from an ESHS30, which operates in the frequency range from 9 kHz to 30 Hz, should not be loaded into an ESVS30 as the data of the two units may be incompatible to because of the different frequency ranges alone (ESVS30: 20 MHz to 1000 MHz). However, in some cases it may be desirable to load an ESVS20 file into an ESVS30, or an ESN file into an ESVN40.
18-Jan-2002 | AN-No. 1EE19
This application note introduces the program GPIB-Bus Device Finder GPIB FIND.The GPIB-Bus Device Finder GPIB FIND helps you identify the devices connected to a GPIB (IEC or IEEE) bus. It shows the addresses of these devices and their response to the identity query (*idn?). Additionally GPIB FIND helps you to locate GPIB problems with GPIB card installation, incorrect address setting or broken cables. GPIB FIND includes an additional program to send (write) a message to a device or to receive (read) a message from the device.
28-Oct-2009 | AN-No. 1MA17
The trigger is a key element of an oscilloscope. It captures specific signal events for detailed analysis and provides a stable view on repeating waveforms. Since its invention in the 1940s the oscilloscope trigger has experienced continuous enhancements. The fully digital trigger of the R&S®RTO digital oscilloscopes sets an innovation milestone that brings significant advantages for the oscilloscope user in terms of measurement accuracy, acquisition density, and functionality. This application note introduces the working principles of a conventional trigger system and explains the advantages of the real-time capable digital trigger of the RTO oscilloscopes.
11-Apr-2012 | AN-No. 1ER04
This educational note covers the theory and practice oscilloscopes based on concrete measurement examples that address authentic everyday tasks.The theoretical portion of this paper begins with an explanation of the basic operating concepts for oscilloscopes, followed by a discussion of the most important parameters to be considered when setting up and performing the exercise measurements. The practical portion of the educational note contains detailed measurement tasks that can be performed by small groups in the university lab. These exercises are intended to demonstrate and reinforce the knowledge gained in the theoretical portion. The exercises build upon one another and demonstrate measurement tasks that are frequently encountered by engineers in daily work.
16-Jan-2018 | AN-No. 1MA265
This document describes how a Windows®-based R&S® T&M instrument is remotely operated by an Android™ tablet as if working on it locally. Step-by-step procedures are provided for setting up and configuring the T&M instrument and the tablet. On the tablet, a special App implements the Windows® 'Remote Desktop' functionality. T&M instrument and tablet are connected via WLAN (also called Wi-Fi network).
22-Aug-2013 | AN-No. 1MA236
A test setup is described for easy demonstration of the Bit Error Rate Test (BERT) function of AMIQ/AMIQ-B1. The test setup contains I/Q Modulation Generator AMIQ/AMIQ-B1 controlled by I/Q Simulation Software WinIQSIM, Vector Signal Generator SMIQ and Spectrum/Vector Signal Analyzer FSE/FSE-B7. The FSE with FSE-B7 is used as online FSK demodulator (setting: Analog demodulation, FM Signal, DC coupling, Real Time On) to demodulate the SMIQ RF signal FSK-modulated by PRBS data. The AMIQ is controlled by WinIQSIM software and receives the demodulated AF output signal from the FSE for BER testing.
29-Sep-1998 | AN-No. 1MA16
This document describes how a Windows®-based R&S® T&M instrument is remotely operated by an Apple iPad as if working on it locally. Step-by-step procedures are provided for setting up and configuring the T&M instrument and the iPad. On the iPad, a special App implements the Windows® 'Remote Desktop' functionality. T&M instrument and iPad are connected via WLAN (also denoted as Wi-Fi network).
28-Mar-2013 | AN-No. 1MA216
Solutions and Tipps for NR FR1 in TDD Downlink Mode
5G New Radio (NR) is a radio technology specified by 3GPP and was first released in 3GPP release 15. It is designed to target three use cases, i.e. enhanced mobile broadband (eMBB), massive machine type communication (mMTC) and ultra-reliable low latency communication (URLLC). Among these three use cases, eMBB represents actually a further evolution of mobile broadband communication from LTE standard. According to the technical performance requirement defined by IMT-2020, by deploying 5G technology, peak data rates of eMBB application are expected to reach 20 Gbps in downlink (DL) and 10 Gbps in uplink (UL) direction, respectively. Typical use cases of eMBB are data hungry applications, such as high resolution 8K video streaming, virtual reality (VR), augmented reality (AR) etc.Verification of a 5G capable user equipment (UE) with respect to its achievable maximum data throughput under controllable and deterministic test conditions is an essential process during the design phase of the product. Performance centric verification through identification of the data throughput bottleneck, product benchmarking against a golden device enhances tremendously the user experience in the end.This document focuses on 5G NR frequency range 1 (FR1) with TDD duplex mode in E-UTRAN New-radio Dual Connectivity (ENDC) operating mode. As 5G NR physical layer offers a plethora of flexibility, the motivation here is to provide a kind of guideline of relevant parameter settings to stimulate device under test (DUT)'s max throughput capacity. The status quo of the R&S solutions at the time when the application note is created are described. Shown feature sets are constantly evolving, so the screenshots used and the parameters shown may change.
07-Jul-2022 | AN-No. 1SL379
Noise figure is an important parameter that describes the noise contribution of an electronic device. A classical approach to measure the noise figure is to use a noise source which delivers two different input noise powers by switching between a “hot” and a “cold” state and a noise receiver (e.g. a spectrum analyzer).In contrast to this approach, using a vector network analyzer with the “Cold Source” approach eliminates the need for a noise source. A cold source noise power measurement followed by an available gain measurement of the device under test is sufficient to determine the noise figure of the device. This application note describes the “Cold Source” technique for measuring noise figure on the R&S®ZNA family of vector network analyzers.Background equations are provided for an analysis of noise factor, noise figure and noise temperature on a device under test and a cascade of devices.Based on a measurement example the user will be guided through the process of setting up a noise figure channel and performing a noise figure measurement. In addition, various measurement options are reviewed, providing guidance as to when and how each option should be utilized to improve the noise figure results.
23-Dec-2021 | AN-No. 1SL378
Verification of baseband data is an important step in the early development phase of LTE/LTE-A-ready products. Comparison values for baseband data (test vectors) from other sources can be very useful in order to verify the correct implementation of the standard. Option K81 for the R&S®SMx200A vector signal generator offers sample data for LTE at the bit level. The reference data enables users to test their own implementation of the specification. The LTE bit stream verification program shown here uses data generated by this option and offers a (bitwise) comparison with bit streams generated for an LTE downlink signal. Therefore it demonstrates, how easy the option R&S SMx-K81 can be integrated into the simulation and design process during the development of LTE/LTE-A handsets or base stations.
02-Feb-2011 | AN-No. 1MA161