Knowledge Center

Embedded

Leverage real-time target machines for use as embedded controllers.

Power Hardware-in-the-Loop

Speedgoat provides a wide range of real-time P-HIL solutions to test and verify power electronics and power system components. Utilize complex physical models designed with MathWorks tools on multi-core CPUs and FPGAs with the highest level of performance.

UAV Modeling and Testing

Create a real-time virtual testing environment to safely test new designs early in the development and avoid expensive reruns of flight campaigns and reduce downtime in the field.

Vorticity Dynamics of Leading-Edge Vortex Formation on a Revolving Wing

A leading-edge vortex (LEV) forms and remains stably attached on high angle-of-attack (AoA), low aspect ratio (AR) wings undergoing revolving or flapping motion at an insect’s wing. Here, the LEV formation on a revolving wing is investigated. The 'Shake-the-box' (STB) Lagrangian particle tracking velocimetry (PTV) system and a volumetric patching process helped reconstruct the entire time-resolved flow field.

Publication on springer.com

HIL of Battery Management Systems

Verify, validate, and test battery management system (BMS) controllers and hardware components using hardware-in-the-loop testing (HIL) and battery cell emulators.

Flight Controller and Autoflight Systems

Develop and test your flight controller or complete auto-flight system with the MathWorks Aerospace Toolbox and Speedgoat systems to simulate conditions for every flight scenario.

Power Management / More Electric Aircraft

Develop and validate power management and control systems for your more electric aircraft using real-time simulation and testing.

Hybrid Aircraft

Simulate and test your electric hybrid hydrogen fuel-cell, and battery propelled aircraft using rapid control prototyping.

FADEC / Engine Controller

Reduce time to market with the MathWorks-Speedgoat workflow for your Engine Control Unit (ECU) or your Full Authority Digital Engine Control (FADEC).

Bypassing

Deploy and test software updates and new hardware builds by implementing a bypassing process in your flight computer.

Sensor Fusion of Vision, Radar and Laser

Develop, improve, and test spectrum monitoring and signal intelligence using solutions from Speedgoat.

RCP for Motor Control Drives

Design, test, and validate novel motor control algorithms for electric motors using Simulink® and Speedgoat hardware. Use a wide range of functionality like PWM, encoders, and many more.

Power Hardware-in-the-Loop

HIL testing of power components like battery chargers using AC or DC power interfaces. Speedgoat supports power amplifiers from EGSTON Power, Cinergia, and Puissance Plus.

ETH Zurich

Efficiently harnessing wind power high above the ground using autonomous kites.

Power Electronics for a more Electric Aircraft

Real-Time Simulation and Testing of Power Electronics.

HIL Testing of BMS using Simulink Real-Time and Speedgoat target hardware

This webinar will demonstrate how engineers can perform hardware-in-the-loop (HIL) testing to validate and test their Battery Management Systems design using Simulink Real-Time^TM and Speedgoat Target hardware.

Rapid Control Prototyping for Power Electronics Control Design

This recorded webinar shows how power electronics control engineers can use rapid control prototyping (RCP) with Simulink Real-Time™ and Speedgoat real-time target machines to validate Simulink^® algorithms against electric motor and power converter prototype systems.

Accelerate Development of Power Systems with Real-Time Testing

This webinar will present how real-time solutions are being used to accelerate electric power generation, renewable energy integration, and onboard systems development. It highlights how Speedgoat real-time solutions enable electrical and control engineers to develop, test, and validate their innovations with hardware prototypes.

HIL and Automated Testing Applications for Aerospace

This recorded webinar presents how hardware-in-the-loop (HIL) testing is used to develop, test, and validate new aircraft components or systems such as controllers for aileron actuators. 

Advancing Electrification with Real-Time Testing

This recorded webinar presents how you can leverage real-time solutions to accelerate renewable energy integration and electric vehicle developments.

Developing and Testing Next Generation Control Systems

Learn how Speedgoat enables you to prototype and test complex control algorithms using full-vehicle simulation. By building a virtual environment for safe and realistic testing and verification, you can reduce prototype testing costs.

Real-Time Simulation and Testing: Hardware-in-the-Loop

Hardware-in-the-Loop (HIL) Simulation and Testing with Simulink Real-Time^TM and Speedgoat target computers.

CPU, FPGA, and I/O Solutions for Real-Time Simulation and Testing with Simulink

In this webinar, MathWorks together with Speedgoat will showcase how to perform real-time simulation and testing, enabling you to rapidly and continuously test and prove your designs, from desktop simulation to testing your designs in real time on hardware platforms.

Leading-Edge Vortex and Transient Lift on a Revolving Wing at Low Reynolds Numbers

The transient formation and the stable attachment of the leading-edge vortex (LEV) contribute to the high lift generation of an insect wing when it revolves at high angles of attack. This study examined the leading-edge vortex (LEV) formation and the transient lift generation on a revolving wing, using combined computational and experimental methods.

Publication on sciencedirect.com

Model-Based Design for Predictive Maintenance, Code Generation and Real-Time Testing

This video shows how to automatically generate C code from classification models. First, you’ll see how to validate your algorithm on the desktop. Then, once it is validated, the video will show how to generate code. Next, the video walks through how to use Simulink® to deploy the classification model onto a B&R PLC, and then test it on a real-time representation of the system using a Speedgoat machine.