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

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Real-Time Simulation and Testing with Simulink Real-Time and Speedgoat Hardware

Real-Time Simulation and Testing with Simulink Real-Time and Speedgoat Hardware

Speedgoat real-time solutions and Simulink® are expressly designed to work together for creating real-time systems for desktop, lab, and field environments.

Workflow Introductions

Hardware-in-the-Loop

Rapid Control Prototyping

Hardware-in-the-Loop Simulation

Hardware-in-the-Loop Simulation

Effectively Test Controls with Real-Time Digital Twins and Automated Testing.

Workflow Introductions

Hardware-in-the-Loop

Industry Use Cases

Rapid Control Prototyping

Rapid Control Prototyping

Accelerate Control Design Innovation With Model-Based Design Ready Solutions for a Worry-Free Test and Simulation Experience.

Workflow Introductions

Rapid Control Prototyping

Industry Use Cases

Introduction to Speedgoat Simulink-Programmable FPGAs

Introduction to Speedgoat Simulink-Programmable FPGAs

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

Workflow Introductions

Hardware-in-the-Loop

Rapid Control Prototyping

FPGA-based rapid control prototyping of permanent magnet synchronous motor servo drives

FPGA-based rapid control prototyping of permanent magnet synchronous motor servo drives

Due to tight time constraints and unknown disturbances, the position control problem in permanent magnet synchronous machine (PMSM) drives remains exceedingly challenging. Download this technical article to learn more about experimental validation of a cascade control structure for position control in PMSM drives.

Whitepapers

Speed Up Digital Control Development for Motors, Power Converters, and Battery Systems with Simulink

Speed Up Digital Control Development for Motors, Power Converters, and Battery Systems with Simulink

Digital control design for power electronics using Simulink® makes it easy to try new ideas, test them, and go to hardware without coding. You can use system-level models for desktop simulation, real-time simulation, and production code generation, speeding up designing and testing your power electronics control systems.

Whitepapers

10 Ways to Speed Design for Digitally Controlled Power Converters with Simulink

10 Ways to Speed Design for Digitally Controlled Power Converters with Simulink

This whitepaper highlights ways to accelerate digital control development for power converters with system-level simulation, how to validate control code on the processor without damaging electrical system hardware and developing real-time simulations of your electrical system.

Hardware-in-the-Loop

Rapid Control Prototyping

Whitepapers

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

Certification Process for a Hybrid Electric Aircraft

Certification Process for a Hybrid Electric Aircraft

The scientific aviation association (FVA) is developing the FVA 30, a hybrid electric motor glider, to research alternative propulsion systems. This article focuses on the certification process of the FVA 30 power train, using a Speedgoat target computer.

Hardware-in-the-Loop

Published Papers

Battery Management System Integration into an Electronic Control Module for a Hybrid Electric Aircraft

Battery Management System Integration into an Electronic Control Module for a Hybrid Electric Aircraft

Th­is article focuses on BMS integration into the electronic control module (ECM) of the FVA 30 hybrid electric motor glider using a Speedgoat real-time target machine. The challenge is to design an ECM for reliable data processing, allowing pilots to monitor and control the drivetrain.

Published Papers

Rapid Control Prototyping

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

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

Published Papers

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

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

Published Papers

Real-Time Learning of Efficient Lift Generation on a Dynamically Scaled Flapping Wing

Real-Time Learning of Efficient Lift Generation on a Dynamically Scaled Flapping Wing

This work presents a successful application of a policy search algorithm to a real-time robotic learning problem, where the goal is to maximize the efficiency of lift generation on a dynamically scaled flapping robotic wing. Learning is performed for different prescribed stroke amplitudes to find the optimal wing pitching amplitude and the stroke-pitch phase difference that maximize lift generation's power loading (PL), a measure of aerodynamic efficiency.

Publication on ieeexplore.ieee.org

Published Papers

Visual Motion Tracking and Sensor Fusion for Kite Power Systems

Visual Motion Tracking and Sensor Fusion for Kite Power Systems

Line-based estimation of the kite state, including position and heading, limits the achievable cycle efficiency of such airborne wind energy systems. Experimental results of a visual motion tracking estimation and an inertial sensor fusion on a ground-based kite power system in pumping operation are presented and compared to an existing estimation scheme based on line.

Publication on springer.com

Published Papers

Transient Engine Emulation within a Laboratory Testbed for Aircraft Power Systems

Transient Engine Emulation within a Laboratory Testbed for Aircraft Power Systems

This paper presents an engine emulation system utilized within a hardware-in-the-loop (HIL) test environment for aircraft power systems. It focuses on the software and hardware interfaces that enable the coupling of the rotor dynamics model that provides the critical link between the modeled dynamics of the engine and the measured dynamics of the generator.

Publication on dx.doi.org

Published Papers

Hardware-in-the-Loop

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