Communications Toolbox provides algorithms and apps for the design, end-to-end simulation, analysis, and verification of communications systems. The toolbox includes a graphically-based app that lets you generate custom- or standard-based waveforms. You can create test vectors to verify receiver performance or to create datasets for artificial intelligence (AI) applications by adding RF impairments to waveforms. The toolbox lets you model propagation channels statistically or with ray-tracing solutions that include terrain and buildings. You can compensate for the effects of channel degradations and use SDRs to verify your designs with over-the-air (OTA) testing.
Communications Toolbox facilitates modeling communications links from antenna to RF chain to bit processing (with Antenna Toolbox and RF Blockset). You can accelerate BER simulations using the cloud or your local cluster (with Parallel Computing Toolbox). The toolbox helps you solve communications problems using AI techniques (with Deep Learning Toolbox).
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Simulate link-level models of communications systems. Explore what-if scenarios and evaluate system parameter tradeoffs. Obtain expected measures of performance such as BER, PER, BLER, and throughput.
Configure, analyze, and visualize link budgets for satellite communications. Analyze availability with the ITU P.618 propagation loss model. Analyze sensitivity with custom line and contour visualizations.
Simulate satellite communications links using DVB-S2/S2X/RCS2, GPS, and CCSDS waveforms. Use receivers built with open MATLAB code to perform all synchronization operations. Analyze link performance by computing bit error rate (BER) and packet error rate (PER) metrics.
The toolbox includes a Waveform Generator app that enables you to create, impair, visualize, and export modulated waveforms, and transmit them over the air. Furthermore, it offers visualization capabilities through constellation and eye diagrams, spectrum analyses, and time-domain plots. The toolbox includes RF impairments, such as memoryless amplifier nonlinearity and carrier offset and compensation algorithms, including carrier and symbol timing synchronizers. These algorithms enable you to realistically model link-level specifications and compensate for the effects of channel degradations.
The toolbox includes Simulink blocks that let you model online supervisory control and perform hardware-in-the-loop controller testing. In both MATLAB and Simulink, you can verify algorithms by establishing a secure OPC UA connection to your plant and build connected digital twin models for IIoT applications. The toolbox also supports communication with edge devices and cloud servers over Modbus and MQTT protocols.
La toolbox incluye bloques de Simulink que permiten modelar control de supervisin online y realizar pruebas de hardware-in-the-loop en controladores. Tanto en MATLAB como en Simulink, puede verificar algoritmos estableciendo una conexin OPC UA segura con la planta y crear modelos de gemelos digitales vinculados para aplicaciones de IIoT. La toolbox tambin soporta la comunicacin con dispositivos edge y servidores en la nube a travs de los protocolos Modbus y MQTT.
Satellite Communications Toolbox provides standards-based tools for designing, simulating, and verifying satellite communications systems and links. The toolbox enables you to model and visualize satellite orbits and perform link analysis and access calculations. You can also design physical layer algorithms together with RF components and ground station receivers, generate test waveforms, and perform golden reference design verification.
With the toolbox you can configure, simulate, measure, and analyze end-to-end satellite communications links. You can also create and reuse tests to verify that your designs, prototypes, and implementations comply with satellite communications and navigations standards, including DVB-S2X, DVB-S2, CCSDS, and GPS.
It comes from a limitation of the Industrial Communication Toolbox OPC UA client. As can be seen in the screenshot below, even when an IP address is directly provided to the opcua function, the toolbox will try to connect using the hostname instead.
The setup process for the Zynq SDR support package does not apply to the High-Speed Converter Toolbox, it just relies upon the core libraries inside of it. The toolbox requires that you are using an ADI authored SD card: -software/linux-software/embedded_arm_images not the one from MathWorks.
Error using matlabshared.libiio.base/cstatusChannel: voltage2_i not foundError in adi.common.Attribute/setAttributeLongLong (line 13) cstatus(obj,status,['Channel: ' id ' not found']);Error in adi.AD9081.Base/CheckAndUpdateHW (line 75) obj.setAttributeLongLong(id,attr,value(k),output, tol, phy);Error in adi.AD9081.Rx/setupInit (line 204) obj.CheckAndUpdateHW(obj.ChannelNCOFrequencies,...Error in adi.common.RxTx/configureChanBuffers (line 219) setupInit(obj);Error in matlabshared.libiio.base/setupImplError in adi.common.RxTx/setupImpl (line 117) setupImpl@matlabshared.libiio.base(obj);Error in Untitled2 (line 7)data = rx();
>> Untitled2Error using matlabshared.libiio.base/cstatusChannel: voltage2_i not foundError in adi.common.Attribute/setAttributeLongLong (line 13) cstatus(obj,status,['Channel: ' id ' not found']);Error in adi.AD9081.Base/CheckAndUpdateHW (line 75) obj.setAttributeLongLong(id,attr,value(k),output, tol, phy);Error in adi.AD9081.Rx/setupInit (line 204) obj.CheckAndUpdateHW(obj.ChannelNCOFrequencies,...Error in adi.common.RxTx/configureChanBuffers (line 219) setupInit(obj);Error in matlabshared.libiio.base/setupImplError in adi.common.RxTx/setupImpl (line 117) setupImpl@matlabshared.libiio.base(obj);Error in Untitled2 (line 7)data = rx();
The toolbox can only be built under Linux or with Cygwin on a Windows platform. Conveniently, the entire process is automated with a Makefile located in the CI/scripts folder of the repository. The following is required on the system before the build process can be run:
I am pretty sure that the reason why this problem happened is because of the license of the toolbox, Communications system toolbook, in which this function belongs in. Write which bi2de and see what will be the result. If it returns path of the function and the comment Has no license available, then the problem is related to the license. That means, license of the toolbox is not set correctly. Mostly it happens if the toolbox is added later, i.e., after installation of the original matlab. Please check and solve the license issue, then it will work fine.
bi2de is a function in the Communications toolbox. You need to have that toolbox to use it. If you do have that toolbox, then the problem is that your B matrix is being treated as double instead of binary (I don't have the toolbox so I can't test this). 17dc91bb1f
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