Space-Time FEM for the Vectorial Wave Equation under Consideration of Ohm’s Law

IF 1 4区数学 Q3 MATHEMATICS, APPLIED Computational Methods in Applied Mathematics Pub Date : 2024-06-25 DOI:10.1515/cmam-2023-0079

Julia I. M. Hauser

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Abstract

The ability to deal with complex geometries and to go to higher orders is the main advantage of space-time finite element methods. Therefore, we want to develop a solid background from which we can construct appropriate space-time methods. In this paper, we will treat time as another space direction, which is the main idea of space-time methods. First, we will briefly discuss how exactly the vectorial wave equation is derived from Maxwell’s equations in a space-time structure, taking into account Ohm’s law. Then we will derive a space-time variational formulation for the vectorial wave equation using different trial and test spaces. This paper has two main goals. First, we prove unique solvability for the resulting Galerkin–Petrov variational formulation. Second, we analyze the discrete equivalent of the equation in a tensor product and show conditional stability, i.e., under a CFL condition. Understanding the vectorial wave equation and the corresponding space-time finite element methods is crucial for improving the existing theory of Maxwell’s equations and paves the way to computations of more complicated electromagnetic problems.

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考虑欧姆定律的矢量波方程时空有限元模型

时空有限元方法的主要优势在于能够处理复杂的几何图形并达到更高的阶次。因此，我们希望建立一个坚实的背景，在此基础上构建适当的时空方法。在本文中，我们将把时间视为另一个空间方向，这也是时空方法的主要思想。首先，我们将简要讨论在时空结构中，考虑到欧姆定律，究竟如何从麦克斯韦方程导出矢量波方程。然后，我们将利用不同的试验和测试空间推导出矢量波方程的时空变分公式。本文有两个主要目标。首先，我们将证明所得到的 Galerkin-Petrov 变式的唯一可解性。其次，我们分析了该方程在张量积中的离散等价物，并展示了条件稳定性，即在 CFL 条件下的稳定性。理解矢量波方程和相应的时空有限元方法对于改进现有的麦克斯韦方程理论至关重要，并为计算更复杂的电磁问题铺平了道路。

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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来源期刊

Computational Methods in Applied Mathematics MATHEMATICS, APPLIED-

CiteScore

2.40

自引率

7.70%

发文量

期刊介绍： The highly selective international mathematical journal Computational Methods in Applied Mathematics　(CMAM) considers original mathematical contributions to computational methods and numerical analysis with applications mainly related to PDEs. CMAM seeks to be interdisciplinary while retaining the common thread of numerical analysis, it is intended to be readily readable and meant for a wide circle of researchers in applied mathematics. The journal is published by De Gruyter on behalf of the Institute of Mathematics of the National Academy of Science of Belarus.