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A Scheme to Improve the Stability and Accuracy of Power Hardware-in-the-Loop Simulation

Zhiwang Feng, Rafael Peña‐Alzola, Paschalis Seisopoulos, Efrén Guilló-Sansano, Mazheruddin Syed, Patrick Norman, Graeme Burt

2020IECON 2020 The 46th Annual Conference of the IEEE Industrial Electronics Society26 citationsDOI

Abstract

Power hardware-in-the-loop (PHIL) is a state-of-the-art simulation technique that combines real-time digital simulation and hardware experiments into a closed-loop testing environment. The transportation delay or communication latency impacts the stability and accuracy of PHIL simulations. In this paper, for the purpose of synchronizing the PHIL out-put signal and promoting both the stability and accuracy of PHIL simulation, a hybrid compensation scheme is proposed to compensate for the time delay in the PHIL configuration. A model-based compensator is implemented to shift the time delay out of the PHIL closed-loop to enhance PHIL stability. A time delay compensation model and its equivalent inverse model are employed in the PHIL closed-loop to compensate for the time delay. A phase lead compensator and digital linear-phase frequency sampling filter (FSF) are candidate compensation models to compensate for the time delay and reshape the phase curve on a harmonic-by-harmonic basis. Simulations are made to validate the effectiveness of the compensation scheme.

Topics & Concepts

Compensation (psychology)SynchronizingControl theory (sociology)Stability (learning theory)Group delay and phase delayComputer scienceHardware-in-the-loop simulationElectronic engineeringHarmonicEngineeringFilter (signal processing)SimulationTelecommunicationsTransmission (telecommunications)Computer visionPhysicsArtificial intelligencePsychoanalysisMachine learningQuantum mechanicsPsychologyControl (management)Real-time simulation and control systemsModeling and Simulation SystemsElectromagnetic Compatibility and Noise Suppression
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