The interior penalty virtual element method for the biharmonic problem

IF 2.1 2区数学 Q1 MATHEMATICS, APPLIED

Mathematics of Computation Pub Date : 2023-02-08 DOI:10.1090/mcom/3828

Jikun Zhao, Shipeng Mao, Bei Zhang, Fei Wang

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引用次数: 1

Abstract

In this paper, an interior penalty virtual element method (IPVEM) is developed for solving the biharmonic problem on polygonal meshes. By modifying the existing H 2 H^2 -conforming virtual element, an H 1 H^1 -nonconforming virtual element is obtained with the same degrees of freedom as the usual H 1 H^1 -conforming virtual element, such that it locally has H 2 H^2 -regularity on each polygon in meshes. To enforce the C 1 C^1 continuity of the solution, an interior penalty formulation is adopted. Hence, this new numerical scheme can be regarded as a combination of the virtual element space and discontinuous Galerkin scheme. Compared with the existing methods, this approach has some advantages in reducing the degree of freedom and capability of handling hanging nodes. The well-posedness and optimal convergence of the IPVEM are proven in a mesh-dependent norm. We also derive a sharp estimate of the condition number of the linear system associated with IPVEM. Some numerical results are presented to verify the optimal convergence of the IPVEM and the sharp estimate of the condition number of the discrete problem. Besides, in the numerical test, the IPVEM has a good performance in computational accuracy by contrast with the other VEMs solving the biharmonic problem.

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双调和问题的内罚虚元法

本文提出了一种求解多边形网格双调和问题的内罚虚元法。通过对已有的符合H^2的虚元进行修改，得到了与一般符合H^1的虚元具有相同自由度的H^1不符合虚元，使其在网格中每个多边形上局部具有H^2正则性。为了使解具有c1 C^1的连续性，采用了内罚公式。因此，这种新的数值格式可以看作是虚元空间与不连续伽辽金格式的结合。与现有方法相比，该方法在降低悬挂节点的自由度和处理能力方面具有一定的优势。在网格相关范数下证明了该算法的适定性和最优收敛性。我们还得到了与IPVEM相关的线性系统的条件数的一个尖锐估计。一些数值结果验证了IPVEM的最优收敛性和离散问题条件数的尖锐估计。此外，在数值试验中，与其他求解双谐波问题的方法相比，IPVEM在计算精度上有较好的表现。

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

Mathematics of Computation 数学-应用数学

CiteScore

3.90

自引率

5.00%

发文量

审稿时长

7.0 months

期刊介绍： All articles submitted to this journal are peer-reviewed. The AMS has a single blind peer-review process in which the reviewers know who the authors of the manuscript are, but the authors do not have access to the information on who the peer reviewers are. This journal is devoted to research articles of the highest quality in computational mathematics. Areas covered include numerical analysis, computational discrete mathematics, including number theory, algebra and combinatorics, and related fields such as stochastic numerical methods. Articles must be of significant computational interest and contain original and substantial mathematical analysis or development of computational methodology.