High-Order Methods Applied to Nonlinear Magnetostatic Problems

High-Order Methods Applied to Nonlinear Magnetostatic Problems

This paper presents a comparison between two high-order modeling methods for solving magnetostatic problems under magnetic saturation, focused on the extraction of machine parameters. Two formulations are compared, the first is based on the Newton-Raphson approach, and the second successively iterat...

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Main Authors: Léo A. J. Friedrich, Mitrofan Curti, Bart L. J. Gysen, Elena A. Lomonova
Format: Article
Language:English
Published: MDPI AG 2019-01-01
Series:Mathematical and Computational Applications
Subjects:
spectral element method
isogeometric analysis
incremental inductance
Online Access:https://www.mdpi.com/2297-8747/24/1/19
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spelling doaj-a37d08a1b8a7405598182f356f59cd882020-11-24T20:48:14ZengMDPI AGMathematical and Computational Applications2297-87472019-01-012411910.3390/mca24010019mca24010019High-Order Methods Applied to Nonlinear Magnetostatic ProblemsLéo A. J. Friedrich0Mitrofan Curti1Bart L. J. Gysen2Elena A. Lomonova3Department of Electrical Engineering, Electromechanics and Power Electronics, Eindhoven University of Technology, 5600 MB Eindhoven, The NetherlandsDepartment of Electrical Engineering, Electromechanics and Power Electronics, Eindhoven University of Technology, 5600 MB Eindhoven, The NetherlandsDepartment of Electrical Engineering, Electromechanics and Power Electronics, Eindhoven University of Technology, 5600 MB Eindhoven, The NetherlandsDepartment of Electrical Engineering, Electromechanics and Power Electronics, Eindhoven University of Technology, 5600 MB Eindhoven, The NetherlandsThis paper presents a comparison between two high-order modeling methods for solving magnetostatic problems under magnetic saturation, focused on the extraction of machine parameters. Two formulations are compared, the first is based on the Newton-Raphson approach, and the second successively iterates the local remanent magnetization and the incremental reluctivity of the nonlinear soft-magnetic material. The latter approach is more robust than the Newton-Raphson method, and uncovers useful properties for the fast and accurate calculation of incremental inductance. A novel estimate for the incremental inductance relying on a single additional computation is proposed to avoid multiple nonlinear simulations which are traditionally operated with finite difference linearization or spline interpolation techniques. Fast convergence and high accuracy of the presented methods are demonstrated for the force calculation, which demonstrates their applicability for the design and analysis of electromagnetic devices.https://www.mdpi.com/2297-8747/24/1/19spectral element methodisogeometric analysisincremental inductance
collection DOAJ
language English
format Article
sources DOAJ
author Léo A. J. Friedrich
Mitrofan Curti
Bart L. J. Gysen
Elena A. Lomonova
spellingShingle Léo A. J. Friedrich
Mitrofan Curti
Bart L. J. Gysen
Elena A. Lomonova
High-Order Methods Applied to Nonlinear Magnetostatic Problems
Mathematical and Computational Applications
spectral element method
isogeometric analysis
incremental inductance
author_facet Léo A. J. Friedrich
Mitrofan Curti
Bart L. J. Gysen
Elena A. Lomonova
author_sort Léo A. J. Friedrich
title High-Order Methods Applied to Nonlinear Magnetostatic Problems
title_short High-Order Methods Applied to Nonlinear Magnetostatic Problems
title_full High-Order Methods Applied to Nonlinear Magnetostatic Problems
title_fullStr High-Order Methods Applied to Nonlinear Magnetostatic Problems
title_full_unstemmed High-Order Methods Applied to Nonlinear Magnetostatic Problems
title_sort high-order methods applied to nonlinear magnetostatic problems
publisher MDPI AG
series Mathematical and Computational Applications
issn 2297-8747
publishDate 2019-01-01
description This paper presents a comparison between two high-order modeling methods for solving magnetostatic problems under magnetic saturation, focused on the extraction of machine parameters. Two formulations are compared, the first is based on the Newton-Raphson approach, and the second successively iterates the local remanent magnetization and the incremental reluctivity of the nonlinear soft-magnetic material. The latter approach is more robust than the Newton-Raphson method, and uncovers useful properties for the fast and accurate calculation of incremental inductance. A novel estimate for the incremental inductance relying on a single additional computation is proposed to avoid multiple nonlinear simulations which are traditionally operated with finite difference linearization or spline interpolation techniques. Fast convergence and high accuracy of the presented methods are demonstrated for the force calculation, which demonstrates their applicability for the design and analysis of electromagnetic devices.
topic spectral element method
isogeometric analysis
incremental inductance
url https://www.mdpi.com/2297-8747/24/1/19
work_keys_str_mv AT leoajfriedrich highordermethodsappliedtononlinearmagnetostaticproblems
AT mitrofancurti highordermethodsappliedtononlinearmagnetostaticproblems
AT bartljgysen highordermethodsappliedtononlinearmagnetostaticproblems
AT elenaalomonova highordermethodsappliedtononlinearmagnetostaticproblems
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