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Jean Mahseredjian

Floating-Point Engines for the FPGA-Based Real-Time Simulation of Power Electronic Circuits

Publication date : Jun 2011
Paper File : Floating-Point Engines for the FPGA-Based.pdf

Authors

Tarek Ould Bachir, Jean-Pierre David, Jean Mahseredjian, Christian Dufour,

Abstract

The real-time simulation of power electronic circuits is challenging for several reasons. A PC-based simulation can hardly achieve time-steps below 5-10 μs: this yields a limit on the maximal power electronic switching frequencies that can be accurately simulated using standard methods. This paper presents a design methodology for the hardware implementation of high-performance FPGA-based floating-point calculation engines aimed for the real-time simulation of power electronic systems. The power electronic circuits are modeled using the associated discrete circuit technique. A calculation time step of 100 ns is achieved for a boost converter, and the simulation results are validated against the SimPowerSystems library. The paper also discusses emerging paradigms for the FPGA-based floatingpoint computation that favor optimal performance and offer near double precision arithmetic at a minimal hardware cost.

Related Products

RT-XSG_en
SimPowerSystems
RT-XSG_fr
ML506 - Integrated FPGA Development System_en

A Combined State-Space Nodal Method for the Simulation of Power System Transients

Publication date : Apr 2011
Paper File : A Combined State-Space Nodal Method for the Simulation of Power System Transients.pdf

Authors

Jean Mahseredjian, Jean Bélanger, Christian Dufour,

Abstract

This paper presents a new solution method that combines state-space and nodal analysis for the simulation of electrical systems. The presented flexible clustering of state-space described electrical subsystems into a nodal method offers several advantages for the efficient solution of switched networks, nonlinear functions and for interfacing with nodal model equations. This paper extends the concept of discrete companion branch equivalent of the nodal approach to state-space described systems and enables natural coupling between them. The presented solution method is simultaneous and allows to benefit from the advantages of two different modeling approaches normally exclusive from one another.

Related Products

ARTEMiS_en
eDRIVEsim Electric Motors, Drives, and Power Electronics High Fidelity Hardware in the Loop (HIL) and ECU Testing_en
eMEGAsim PowerGrid Real-Time Digital Hardware in the Loop Simulator_en
HIL Box_en
SimPowerSystems
eDRIVEsim - Simulateur Temps Réel pour les Moteurs et Systèmes Électriques_fr
eMEGAsim_fr
ARTEMiS_fr
HIL Box_fr
SimPowerSystems (The MathWorks product)_en
Simulink - Simulation and Model-Based Design (The MathWorks Product)_en


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Jean Mahseredjian Floating-Point Engines for the FPGA-Based Real-Time Simulation of Power Electronic Circuits Publication date : Jun 2011 Paper File : Floating-Point Engines for the FPGA-Based.pdf Authors Tarek Ould Bachir, Jean-Pierre David, Jean Mahseredjian, Christian Dufour, Abstract The real-time simulation of power electronic circuits is challenging for several reasons. A PC-based simulation can hardly achieve time-steps below 5-10 μs: this yields a limit on the maximal power electronic switching frequencies that can be accurately simulated using standard methods. This paper presents a design methodology for the hardware implementation of high-performance FPGA-based floating-point calculation engines aimed for the real-time simulation of power electronic systems. The power electronic circuits are modeled using the associated discrete circuit technique. A calculation time step of 100 ns is achieved for a boost converter, and the simulation results are validated against the SimPowerSystems library. The paper also discusses emerging paradigms for the FPGA-based floatingpoint computation that favor optimal performance and offer near double precision arithmetic at a minimal hardware cost. Related Products RT-XSG_en SimPowerSystems RT-XSG_fr ML506 - Integrated FPGA Development System_en A Combined State-Space Nodal Method for the Simulation of Power System Transients Publication date : Apr 2011 Paper File : A Combined State-Space Nodal Method for the Simulation of Power System Transients.pdf Authors Jean Mahseredjian, Jean Bélanger, Christian Dufour, Abstract This paper presents a new solution method that combines state-space and nodal analysis for the simulation of electrical systems. The presented flexible clustering of state-space described electrical subsystems into a nodal method offers several advantages for the efficient solution of switched networks, nonlinear functions and for interfacing with nodal model equations. This paper extends the concept of discrete companion branch equivalent of the nodal approach to state-space described systems and enables natural coupling between them. The presented solution method is simultaneous and allows to benefit from the advantages of two different modeling approaches normally exclusive from one another. Related Products ARTEMiS_en eDRIVEsim Electric Motors, Drives, and Power Electronics High Fidelity Hardware in the Loop (HIL) and ECU Testing_en eMEGAsim PowerGrid Real-Time Digital Hardware in the Loop Simulator_en HIL Box_en SimPowerSystems eDRIVEsim - Simulateur Temps Réel pour les Moteurs et Systèmes Électriques_fr eMEGAsim_fr ARTEMiS_fr HIL Box_fr SimPowerSystems (The MathWorks product)_en Simulink - Simulation and Model-Based Design (The MathWorks Product)_en

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