research-article

Model order reduction of an electro-quasistatic problem using CLN method

Authors:

Thomas Henneron,

Stéphane Clénet,

Théo Delagnes,

Jun ZouAuthors Info & Claims

Volume 238, Issue C

https://doi.org/10.1016/j.finel.2024.104185

Published: 19 September 2024 Publication History

Abstract

The Cauer ladder network (CLN) method, as proposed by Kameari et al. (2018), has been extensively studied to construct a reduced model of magneto-quasistatic (MQS) Finite Element (FE) models. In this case, this method enables the construction of an equivalent electrical circuit based on resistances and inductances as well as a reduced basis where the solution of a reduced problem is sought. In this article, we propose to extend the applicability of the CLN method to the development of reduced models for FE electro-quasistatic (EQS) models. It appears that the derivation of the reduction of an EQS model is not similar to the one of an MQS model. After development, the process of reduction using CLN leads to consider two electrical circuits based on the cascade association of resistances and capacitances. Each circuit is associated with a reduced basis constructed by applying the self-adjoint Lanczos method. The reduced solution to the EQS problem is got by first solving the circuit equations to determine the voltages and the currents at the terminals of the resistances and capacitances. Then, the approximated solution of the FE EQS model is got by a linear combination of the vectors of the two reduced bases weighted by the currents (or the voltages) previously calculated. An error estimator is also derived, enabling to calculate the distance between the reduced solution and the FE solution without solving the FE model. The proposed approach has been applied on an industrial application, a resin-impregnated paper bushing, in order to evaluate the accuracy in function of the size of the reduced bases as well as the efficiency in terms of computation time.

Highlights

•

Application of Cauer Ladder Network (CLN) method to reduce electro-quasistatic (EQS) problems.

•

Derivation from the FE EQS model of an equivalent electrical circuit.

•

Derivation of an estimator of the reduction error due to CLN method.

•

Application of the CLN method to study an industrial EQS problem.

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Index Terms

Model order reduction of an electro-quasistatic problem using CLN method
1. Applied computing
2. Computing methodologies

Index terms have been assigned to the content through auto-classification.

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Published In

cover image Finite Elements in Analysis and Design

Finite Elements in Analysis and Design Volume 238, Issue C

Oct 2024

61 pages

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Elsevier B.V.

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Elsevier Science Publishers B. V.

Netherlands

Publication History

Published: 19 September 2024

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