Accurate Fundamental Harmonic Modeling of Inductive Power Transfer Battery Chargers

This article presents a precise fundamental harmonic approximation (FHA) for modeling series-series compensated inductive power transfer (IPT) systems with constant voltage load, e.g., with battery load. In comparison with previous works, not only an FHA model is devised but also the model is modifi...

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Veröffentlicht in:	IEEE transactions on transportation electrification 2022-03, Vol.8 (1), p.627-635
Hauptverfasser:	Namadmalan, Alireza, Alonso, Jose Marcos, Iqbal, Atif
Format:	Artikel
Sprache:	eng
Schlagworte:	Batteries Battery chargers Battery load Computational modeling Electric potential fundamental harmonic approximation (FHA) Harmonic analysis harmonics Higher harmonics inductive power transfer (IPT) Integrated circuit modeling IPT modeling Iterative methods Iterative solution Load modeling Mathematical model Modelling Power transfer Rectifiers Time domain analysis Voltage
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creator	Namadmalan, Alireza Alonso, Jose Marcos Iqbal, Atif
description	This article presents a precise fundamental harmonic approximation (FHA) for modeling series-series compensated inductive power transfer (IPT) systems with constant voltage load, e.g., with battery load. In comparison with previous works, not only an FHA model is devised but also the model is modified to reduce the errors of conventional FHA methods. This improvement is done by considering the intrinsic effect of higher order harmonics, which generates a displacement between fundamental current and voltage at the secondary side. Moreover, the precise model can easily derive the frequency responses and Bode plots for IPT systems with constant voltage load, which is the essential step for appropriate modeling and design. In comparison with iterative solutions and time-domain analysis (TDA) tools, the proposed modeling leads to a time-efficient and straightforward formulation with excellent accuracy. The results of the modified FHA, derived by MATLAB codes, are compared with TDA simulations by using PSIM. Finally, the simulation results are verified by a laboratory prototype.
doi_str_mv	10.1109/TTE.2021.3072832
format	Article
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In comparison with previous works, not only an FHA model is devised but also the model is modified to reduce the errors of conventional FHA methods. This improvement is done by considering the intrinsic effect of higher order harmonics, which generates a displacement between fundamental current and voltage at the secondary side. Moreover, the precise model can easily derive the frequency responses and Bode plots for IPT systems with constant voltage load, which is the essential step for appropriate modeling and design. In comparison with iterative solutions and time-domain analysis (TDA) tools, the proposed modeling leads to a time-efficient and straightforward formulation with excellent accuracy. The results of the modified FHA, derived by MATLAB codes, are compared with TDA simulations by using PSIM. 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In comparison with previous works, not only an FHA model is devised but also the model is modified to reduce the errors of conventional FHA methods. This improvement is done by considering the intrinsic effect of higher order harmonics, which generates a displacement between fundamental current and voltage at the secondary side. Moreover, the precise model can easily derive the frequency responses and Bode plots for IPT systems with constant voltage load, which is the essential step for appropriate modeling and design. In comparison with iterative solutions and time-domain analysis (TDA) tools, the proposed modeling leads to a time-efficient and straightforward formulation with excellent accuracy. The results of the modified FHA, derived by MATLAB codes, are compared with TDA simulations by using PSIM. 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In comparison with previous works, not only an FHA model is devised but also the model is modified to reduce the errors of conventional FHA methods. This improvement is done by considering the intrinsic effect of higher order harmonics, which generates a displacement between fundamental current and voltage at the secondary side. Moreover, the precise model can easily derive the frequency responses and Bode plots for IPT systems with constant voltage load, which is the essential step for appropriate modeling and design. In comparison with iterative solutions and time-domain analysis (TDA) tools, the proposed modeling leads to a time-efficient and straightforward formulation with excellent accuracy. The results of the modified FHA, derived by MATLAB codes, are compared with TDA simulations by using PSIM. 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subjects	Batteries Battery chargers Battery load Computational modeling Electric potential fundamental harmonic approximation (FHA) Harmonic analysis harmonics Higher harmonics inductive power transfer (IPT) Integrated circuit modeling IPT modeling Iterative methods Iterative solution Load modeling Mathematical model Modelling Power transfer Rectifiers Time domain analysis Voltage
title	Accurate Fundamental Harmonic Modeling of Inductive Power Transfer Battery Chargers
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