Coupling of Vector and Scalar Boundary Element Methods

2021 XV International Scientific-Technical Conference on Actual Problems Of Electronic Instrument Engineering (APEIE) Pub Date : 2021-11-19 DOI:10.1109/apeie52976.2021.9647694

S. Sivak, M. Royak, I. Stupakov

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Abstract

The vector boundary element method is a tool applied to solve electromagnetic problems in a media for which eddy currents must be taken into account. It's also known as the boundary element method for eddy current problems. The use of this method brings certain difficulties, one of which is the problem of zero wave number in the subdomains adjacent to the domain where the eddy currents should be considered. To mitigate the computational difficulty, we use the coupling with the scalar potential. The scalar boundary element method for the Laplace equation is in use for the corresponding adjacent subdomains with zero wave number and the associated scalar potential. In this paper, we present the system of variational equations written in a weak form and based on the Steklov-Poincare operators formulated for both scalar and vector boundary element methods. This coupling is supported with a simple test problem considering a conducting cube and a time-harmonic source of electromagnetic field.

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向量与标量边界元方法的耦合

矢量边界元法是一种用于求解必须考虑涡流的介质中的电磁问题的工具。它也被称为涡流问题的边界元法。这种方法的使用带来了一定的困难，其中之一是在需要考虑涡流的邻域的子域中存在零波数问题。为了减轻计算难度，我们使用了与标量势的耦合。对于相应的波数为零的相邻子域及其相关的标量势，采用拉普拉斯方程的标量边界元法。在本文中，我们给出了一个基于Steklov-Poincare算子的弱形式的变分方程组。用一个简单的测试问题来支持这种耦合，该测试问题考虑了导体立方体和电磁场的时谐源。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 XV International Scientific-Technical Conference on Actual Problems Of Electronic Instrument Engineering (APEIE)

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