Knowledge Center search search close
Collection of videos, reference examples, and more to support your real-time simulation and testing workflows

Content

Hardware-in-the-Loop Testing for Electric Powertrains

Hardware-in-the-Loop Testing for Electric Powertrains

Advance EV powertrain testing: real-time digital twin simulation, modular hardware-in-the-loop test benches, end-to-end automation. 

Recorded Webinars

Hardware-in-the-Loop

System Testing and Validation Using Hardware-in-the-Loop (HIL)

System Testing and Validation Using Hardware-in-the-Loop (HIL)

See how to leverage HIL testing using a Speedgoat target machine to streamline your controller development process

Recorded Webinars

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of Battery Management Systems

Hardware-in-the-Loop Testing of Battery Management Systems

Learn how to test and validate battery management systems (BMS) using a Simulink workflow from desktop simulation to hardware-in-the-loop (HIL) testing.

Recorded Webinars

Hardware-in-the-Loop

Developing and Testing Motors and Drives for Vehicles and Robots

Developing and Testing Motors and Drives for Vehicles and Robots

Prototype motor control designs, and test motor drives using a fully connected model-based environment and digital twin simulation.

Recorded Webinars

Hardware-in-the-Loop

Rapid Control Prototyping

Hardware-in-the-Loop Testing of Battery Management Systems

Hardware-in-the-Loop Testing of Battery Management Systems

Expedite testing of Battery Management Systems (BMS) with hardware-in-the-loop (HIL) simulation and battery cell emulation

Reference Examples

Hardware-in-the-Loop

How to Configure a Speedgoat Test System for Simulink Real-Time

How to Configure a Speedgoat Test System for Simulink Real-Time

Configuring your Speedgoat machine for Simulink Real-Time: A Step-by-Step Guide

How To

Controller HIL Testing for Induction Motor

Controller HIL Testing for Induction Motor

Accelerate testing of embedded motor controllers by simulating a three-phase induction motor drive as hardware-in-the-loop

Reference Examples

Hardware-in-the-Loop

Controller HIL Testing of Grid-side Converter

Controller HIL Testing of Grid-side Converter

Advance integration of grid-tied converters for renewables and distributed energy sources using hardware in the loop testing

Reference Examples

Hardware-in-the-Loop

Controller HIL Testing of LLC Resonant Converter

Controller HIL Testing of LLC Resonant Converter

Accelerate testing of embedded DC/DC power converter controllers by simulating a half-bridge LLC resonant converter as hardware-in-the-loop

Reference Examples

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of Unmanned Aerial Vehicle (UAV) Controllers

Hardware-in-the-Loop Testing of Unmanned Aerial Vehicle (UAV) Controllers

Test your UAV controllers, design and tune your controllers through Simulink, 

Recorded Webinars

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of Industrial Equipment Controllers

Hardware-in-the-Loop Testing of Industrial Equipment Controllers

Learn how you can perform hardware-in-the-loop testing of industrial equipment controllers using Speedgoat test systems that provide unrivaled integration with Simulink

Recorded Webinars

Hardware-in-the-Loop

Speedgoat Configurable I/O Modules

Speedgoat Configurable I/O Modules

Learn about the Simulink-integrated workflows to configure I/O modules easily and directly from your model.

Workflow Introductions

Hardware-in-the-Loop

Rapid Control Prototyping

Hardware-in-the-Loop Testing for Electric Motor Control

Hardware-in-the-Loop Testing for Electric Motor Control

Learn about full-scale testing and validation of new controller algorithms under all conditions, including edge cases, using Simulink and Speedgoat test systems.

Recorded Webinars

Hardware-in-the-Loop

Controller HIL Testing for Three-Phase PMSM with Two-Level Inverter

Controller HIL Testing for Three-Phase PMSM with Two-Level Inverter

Accelerate testing of embedded motor controllers by simulating a three-phase PMSM drive as hardware-in-the-loop

Reference Examples

Hardware-in-the-Loop

Implementing a PLCnext-Based Turbine Control System in Simulink - Sokratel

Implementing a PLCnext-Based Turbine Control System in Simulink - Sokratel

Find out how Sokratel uses continuous integration (CI/CD) frameworks to continuously test their turbine control systems using Speedgoat test systems

Customer Success Stories

Verification of Avionics Systems Using Simulink Test and Simulink Real-Time - GE Aerospace

Verification of Avionics Systems Using Simulink Test and Simulink Real-Time - GE Aerospace

Find out how GE Aerospace uses an integrated requirements-based testing approach for controller certification using Speedgoat test systems

Customer Success Stories

Accelerating Safe Railway Application Development Using Model-Based Design - Alstom

Accelerating Safe Railway Application Development Using Model-Based Design - Alstom

Find out how Alstom employs requirements-based testing to develop safety-critical train controls using Speedgoat test systems

Customer Success Stories

Managing the Complexity of FPGA-Based Rapid Control Prototyping - Siemens Healthineers

Managing the Complexity of FPGA-Based Rapid Control Prototyping - Siemens Healthineers

Find out how Siemens Healthineers rapidly prototype controls to accelerate development of their X-ray imaging devices using Speedgoat test systems equipped with ultra-fast FPGAs

Customer Success Stories

Validating Motor Control Algorithms with Hardware-In-The-Loop Testing

Validating Motor Control Algorithms with Hardware-In-The-Loop Testing

Learn how to develop and test motor control algorithms. See how you can validate the embedded software by performing hardware-in-the-loop (HIL) testing of the control algorithms

Recorded Webinars

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of More Electric Aircraft Energy Management System

Hardware-in-the-Loop Testing of More Electric Aircraft Energy Management System

This reference example demonstrates how to perform model-in-the-loop (MIL) and hardware-in-the-loop (HIL) testing of an energy magement system (EMS) design for a More Electric Aircraft (MEA).

Reference Examples

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of Microgrid Energy Management System

Hardware-in-the-Loop Testing of Microgrid Energy Management System

This reference example demonstrates how to perform model-in-the-loop (MIL) and hardware-in-the-loop (HIL) simulation of a grid-connected/islanded microgrid.

Reference Examples

Hardware-in-the-Loop

Hardware-in-the-Loop Testing of a Shipboard Power System

Hardware-in-the-Loop Testing of a Shipboard Power System

This reference example demonstrates how to perform model-in-the-loop (MIL) and hardware-in-the-loop (HIL) simulation of a two-zone medium voltage direct current (MVDC) shipboard power system.

Reference Examples

Hardware-in-the-Loop

Real-Time Testing for VTOL and Conventional Aircraft Development

Real-Time Testing for VTOL and Conventional Aircraft Development

Learn how Simulink Real-Time™ enables real-time controls testing to ensure safety and performance in advanced aircraft designs, including transitioning from desktop simulation, in the webinar highlighting the challenges of aircraft electrification.

Hardware-in-the-Loop

Rapid Control Prototyping

Recorded Webinars

Hiroshima University

Hiroshima University

Testing with a digital twin allows adjusting control parameters or evaluating new control designs seamlessly

Hardware-in-the-Loop

Customer Success Stories

Designing a Generic, Software-Defined Multimode Radar Simulator For FPGAs Using Simulink HDL Coder and Speedgoat Real-Time Hardware

Designing a Generic, Software-Defined Multimode Radar Simulator For FPGAs Using Simulink HDL Coder and Speedgoat Real-Time Hardware

This publication focuses on the implementation and testing of a fully-parameterized radar signal processing prototype. A Speedgoat Performance machine with two Simulink-Programmable FPGA I/O modules IO342 are used for the implementation of a radar signal processing design containing several common waveforms and tunable parameters and a radar scene generator for delay, doppler, and amplitude measurement.This setup helped increase the simulation fidelity while reducing the time to test.

Published Papers

Follow Speedgoat LinkedIn