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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 FPGA Technology

Introduction to Speedgoat FPGA Technology

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

Workflow Introductions

Hardware-in-the-Loop

Rapid Control Prototyping

Experimental and Finite Element Studies of a 250 kW Brushless Doubly Fed Induction Generator

Experimental and Finite Element Studies of a 250 kW Brushless Doubly Fed Induction Generator

Brushless doubly fed induction generator (BDFIG) can replace doubly fed slip-ring induction generators for offshore wind power generation. This study uses experimentally verified finite element (FE) analysis, various performance measures of the BDFIG when magnetic wedges are used for closing stator open slots to show that the use of magnetic wedges increases the performance of the generator. 

Publication on ieeexplore.ieee.org

Published Papers

Power Hardware in-the-Loop Validation of DC-DC Power Converter

Power Hardware in-the-Loop Validation of DC-DC Power Converter

The paper describes the development of a power converter small-scale mock-up and a real-time model of an offshore wind farm. Power Hardware In-the-Loop (PHIL) validation is proposed for a demonstration of grid architecture and control principles. Results obtained with a test bench underline the importance of PHIL testing in the power converter development for DC grid applications.

Publication on ieeexplore.ieee.org

Published Papers

Experimental Validation of Model Predictive Control Applied to the Azura Wave Energy Converter

Experimental Validation of Model Predictive Control Applied to the Azura Wave Energy Converter

Ocean wave energy is a promising area of renewable energy development. However, there are unique operational challenges, particularly modeling, estimation, and control. This article presents a model-predictive control (MPC) formulation and its experimental testing applied to the 1/15th scale Azura wave energy converter developed by Northwest Energy Innovations (NWEI).

Publication on ieeexplore.ieee.org

Published Papers

Software Simulation Tool for Design of the Energy Management System in Elevators

Software Simulation Tool for Design of the Energy Management System in Elevators

This work shows the development of a software tool that provides realistic operation power profiles in elevators for residential and public buildings applications to accelerate Energy Management System prototyping. The simulator is validated and verified through computer simulations, through a HIL (Hardware-in-the- Loop) platform and is finally validated using a full-scale laboratory prototype.

Publication on ieeexplore.ieee.org

Published Papers

Wave Tank and Bench-Top Control Testing of a Wave Energy Converter

Wave Tank and Bench-Top Control Testing of a Wave Energy Converter

This paper details the design and execution of an experiment for evaluating the capability of model-scale wave energy converters to execute basic real-time realizations of prospective control algorithms. Model-scale hardware, system, and experimental designs are considered, meeting the dynamic requirements of a control system. A dry bench testing method is proposed and utilized for efficient rapid control prototyping.

Publication on sciencedirect.com

Published Papers

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