具有动力学边界条件的半线性声波方程的有限元离散化

IF 0.8 4区数学 Q3 MATHEMATICS, APPLIED

Electronic Transactions on Numerical Analysis Pub Date : 2020-01-01 DOI:10.1553/ETNA_VOL53S522

M. Hochbruck, Jan Leibold

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引用次数: 9

摘要

我们考虑具有动力学边界条件的半线性声波方程的等参有限元离散化，并推导出相应的误差界作为我们的主要结果。困难之处在于这些问题是在具有弯曲边界的域上表述的，这使得离散化不一致。我们的方法是为半线性波动方程的非一致性空间离散提供统一的误差分析。特别地，我们引入了非一致性空间离散化的一般抽象框架，在该框架中，我们推导了插值误差、数据误差和一致性误差的先验误差界。该理论适用于符合抽象框架的大量问题和离散化。在统一误差分析的抽象误差结果中插入已知的插值和几何误差边界，从一般理论推导出具有运动边界条件的波动方程的误差边界。

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Finite element discretization of semilinear acoustic wave equations with kinetic boundary conditions

We consider isoparametric finite element discretizations of semilinear acoustic wave equations with kinetic boundary conditions and derive a corresponding error bound as our main result. The difficulty is that such problems are stated on domains with curved boundaries and this renders the discretizations nonconforming. Our approach is to provide a unified error analysis for nonconforming space discretizations for semilinear wave equations. In particular, we introduce a general, abstract framework for nonconforming space discretizations in which we derive a-priori error bounds in terms of interpolation, data and conformity errors. The theory applies to a large class of problems and discretizations that fit into the abstract framework. The error bound for wave equations with kinetic boundary conditions is obtained from the general theory by inserting known interpolation and geometric error bounds into the abstract error result of the unified error analysis.

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来源期刊

Electronic Transactions on Numerical Analysis 数学-应用数学

CiteScore

2.10

自引率

7.70%

发文量

审稿时长

6 months

期刊介绍： Electronic Transactions on Numerical Analysis (ETNA) is an electronic journal for the publication of significant new developments in numerical analysis and scientific computing. Papers of the highest quality that deal with the analysis of algorithms for the solution of continuous models and numerical linear algebra are appropriate for ETNA, as are papers of similar quality that discuss implementation and performance of such algorithms. New algorithms for current or new computer architectures are appropriate provided that they are numerically sound. However, the focus of the publication should be on the algorithm rather than on the architecture. The journal is published by the Kent State University Library in conjunction with the Institute of Computational Mathematics at Kent State University, and in cooperation with the Johann Radon Institute for Computational and Applied Mathematics of the Austrian Academy of Sciences (RICAM).