On forward and inverse energy-based magnetic vector hysteresis operators

Herbert Egger; Felix Engertsberger; Lukas Domenig; Klaus Roppert; Manfred Kaltenbacher

doi:10.1109/TMAG.2025.3544507

On forward and inverse energy-based magnetic vector hysteresis operators

Herbert Egger^*, Felix Engertsberger, Lukas Domenig, Klaus Roppert, Manfred Kaltenbacher

^*Korrespondierende/r Autor/-in für diese Arbeit

Institut für Grundlagen und Theorie der Elektrotechnik (4370)

Publikation: Beitrag in einer Fachzeitschrift › Artikel › Begutachtung

Abstract

Incremental models for magnetic vector hysteresis have been developed in previous works in accordance with basic principles of thermodynamics. In this paper, we derive an equivalent representation of the associated hysteresis operator in terms of a co-energy functional which is useful for magnetic field computations based on a scalar potential. Using convex duality, we further define the corresponding energy functional and the associated inverse hysteresis operator which is required for computations based on the vector potential. The equivalence of the two representations with the energy-based hysteresis models proposed in earlier works is demonstrated and numerical results for some typical test problems are presented obtained by finite element simulation of corresponding scalar and vector potential formulations.

Originalsprache	englisch
Fachzeitschrift	IEEE Transactions on Magnetics
Jahrgang	61
Ausgabenummer	4
Frühes Online-Datum	21 Feb. 2025
DOIs	https://doi.org/10.1109/TMAG.2025.3544507
Publikationsstatus	Veröffentlicht - Apr. 2025

ASJC Scopus subject areas

Elektronische, optische und magnetische Materialien
Elektrotechnik und Elektronik

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abstract = "Incremental models for magnetic vector hysteresis have been developed in previous works in accordance with basic principles of thermodynamics. In this paper, we derive an equivalent representation of the associated hysteresis operator in terms of a co-energy functional which is useful for magnetic field computations based on a scalar potential. Using convex duality, we further define the corresponding energy functional and the associated inverse hysteresis operator which is required for computations based on the vector potential. The equivalence of the two representations with the energy-based hysteresis models proposed in earlier works is demonstrated and numerical results for some typical test problems are presented obtained by finite element simulation of corresponding scalar and vector potential formulations.",

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author = "Herbert Egger and Felix Engertsberger and Lukas Domenig and Klaus Roppert and Manfred Kaltenbacher",

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AU - Egger, Herbert

AU - Engertsberger, Felix

AU - Domenig, Lukas

AU - Roppert, Klaus

AU - Kaltenbacher, Manfred

PY - 2025/4

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N2 - Incremental models for magnetic vector hysteresis have been developed in previous works in accordance with basic principles of thermodynamics. In this paper, we derive an equivalent representation of the associated hysteresis operator in terms of a co-energy functional which is useful for magnetic field computations based on a scalar potential. Using convex duality, we further define the corresponding energy functional and the associated inverse hysteresis operator which is required for computations based on the vector potential. The equivalence of the two representations with the energy-based hysteresis models proposed in earlier works is demonstrated and numerical results for some typical test problems are presented obtained by finite element simulation of corresponding scalar and vector potential formulations.

AB - Incremental models for magnetic vector hysteresis have been developed in previous works in accordance with basic principles of thermodynamics. In this paper, we derive an equivalent representation of the associated hysteresis operator in terms of a co-energy functional which is useful for magnetic field computations based on a scalar potential. Using convex duality, we further define the corresponding energy functional and the associated inverse hysteresis operator which is required for computations based on the vector potential. The equivalence of the two representations with the energy-based hysteresis models proposed in earlier works is demonstrated and numerical results for some typical test problems are presented obtained by finite element simulation of corresponding scalar and vector potential formulations.

KW - energy-based models

KW - finite element methods

KW - inverse hysteresis operator

KW - Magnetic vector hysteresis

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JO - IEEE Transactions on Magnetics

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On forward and inverse energy-based magnetic vector hysteresis operators

Abstract

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