Power Electronics Solutions Design, test, and validate digital controls for electric motors, power converters, and battery management systems. Industry Use Cases Rapid Control Prototyping Hardware-in-the-Loop
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 Effectively Test Controls with Real-Time Digital Twins and Automated Testing. Workflow Introductions Hardware-in-the-Loop Industry Use Cases
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 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
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
RCP for Wide Bandgap Semiconductors Control power modules using SiC or GaN wide bandgap (WBG) semiconductors. Speedgoat real-time systems can handle controllers for switching frequencies up to 2 MHz. Industry Use Cases Rapid Control Prototyping
Virtual Commissioning Test and automate testing of large-scale industrial plants and networks with hundreds or thousands of nodes leveraging real protocol interconnects, provided by hardware chips that are used in millions of embedded devices. Hardware-in-the-Loop Industry Use Cases
Computer Vision Rapidly build, run, and test video acquisition and control applications with a Speedgoat real-time target machine. There is a wide range of applications from the design of phone cameras to autonomous vehicle systems. Rapid Control Prototyping Hardware-in-the-Loop Industry Use Cases
Audio Highly controlled manipulations are required e.g. for hearing aids, noise cancelling headphones, or car acoustics. Speedgoat real-time systems provide high performance, high-resolution analog and digital I/O, together with MATLAB & Simulink. Rapid Control Prototyping Hardware-in-the-Loop Industry Use Cases
Embedded Leverage real-time target machines for use as embedded controllers. Rapid Control Prototyping Industry Use Cases
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. Hardware-in-the-Loop Industry Use Cases
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. Industry Use Cases Hardware-in-the-Loop
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. Industry Use Cases Rapid Control Prototyping
HIL Testing of Electric Motor Controls Test, and validate embedded controllers for electric motors and drives using Simulink and Speedgoat hardware. Emulate electric motors, inverters, resolvers, among other components. Industry Use Cases Hardware-in-the-Loop
RCP for Power Converter Control Use Simulink and Speedgoat to develop power converters with high-frequency switching such as high-voltage DC (HVDC), DC/DC converters, grid-tied inverters, grid-forming inverters, and many more. Industry Use Cases Rapid Control Prototyping
HIL Testing of Power Electronics Accelerate the development of power electronic converters such as DC/DC, AC/DC, or MMC using hardware-in-the-loop testing. Industry Use Cases Hardware-in-the-Loop
Electric Vehicle Powertrains Develop powertrains and fast chargers for electric vehicles including electric motors, inverters, transmissions, and power management systems. Industry Use Cases Rapid Control Prototyping Hardware-in-the-Loop
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. Industry Use Cases Hardware-in-the-Loop
HIL of Grid-Side Inverter Controllers Advance control development using HIL testing. Reuse models from desktop simulation and include switching dynamics up to 5 kHz using CPUs or 100 kHz with FPGAs. Industry Use Cases Hardware-in-the-Loop
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 28 Nov 2019 Published Papers
An Intelligent Controller based Power Grid Interconnected System for Reliable Operation The main objective of the research presented is to control the unidirectional boost converter (UBC) by implementing an intelligent controller (IC). The IC continuously captures power conversion based on power output data from wind and solar energy. Then, it injects gate pulses into a power electronic switch based on the data value. The overall design and simulations are performed using MATLAB/SIMULINK. Publication on ieeexplore.ieee.org 27 Mar 2019 Rapid Control Prototyping Published Papers
Phase-Exact Adaptive Feedforward Control Modulated Gear Mesh Vibration at 4.7 kHz This paper proposes a setup for active vibration control to suppress transmission of gear mesh vibration to the surrounding structure using piezoelectric inertial mass actuators. The proposed control algorithm uses multiple adaptive feedforward controllers. To achieve the desired sampling frequency in real-time several optimizations are introduced. Publication on ieeexplore.ieee.org 11 Sep 2018 Published Papers
Design and Implementation of Bi-Directional DC-DC Converter for Wind Energy System This paper features designing and implementing a bi-directional DC-DC converter with a Speedgoat controller for wind energy conversion systems. An energy storage device is used to compensate for the fluctuations and to maintain a smooth and continuous power flow in all operating modes to load. The complete system is implemented in MATLAB/SIMULINK and verified with hardware. Publication on scirp.org 01 Sep 2016 Published Papers Rapid Control Prototyping
Fault Diagnosis of Star-Connected Auto-Transformer-Based 24-Pulse Rectifier The authors propose a fault diagnosis method for star-connected auto-transformer-based 24-pulse rectifier unit (ATRU) by integrating artificial neural networks (ANN) with wavelet packet decomposition (WPD) and principal component analysis (PCA). First, the fault features are extracted and simulated in a real-time simulation platform. The obtained data is then analyzed with MATLAB toolboxes and verified with a digital signal processor. Publication on sciencedirect.com 01 Sep 2016 Published Papers