Higher-order FEM and CIP-FEM for Helmholtz equation with high wave number and perfectly matched layer truncation

arXiv - CS - Numerical Analysis Pub Date : 2023-12-05 DOI:arxiv-2312.02476

Yonglin Li, Haijun Wu

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Abstract

The high-frequency Helmholtz equation on the entire space is truncated into a bounded domain using the perfectly matched layer (PML) technique and subsequently, discretized by the higher-order finite element method (FEM) and the continuous interior penalty finite element method (CIP-FEM). By formulating an elliptic problem involving a linear combination of a finite number of eigenfunctions related to the PML differential operator, a wave-number-explicit decomposition lemma is proved for the PML problem, which implies that the PML solution can be decomposed into a non-oscillating elliptic part and an oscillating but analytic part. The preasymptotic error estimates in the energy norm for both the $p$-th order CIP-FEM and FEM are proved to be $C_1(kh)^p + C_2k(kh)^{2p} +C_3 E^{\rm PML}$ under the mesh condition that $k^{2p+1}h^{2p}$ is sufficiently small, where $k$ is the wave number, $h$ is the mesh size, and $E^{\rm PML}$ is the PML truncation error which is exponentially small. In particular, the dependences of coefficients $C_j~(j=1,2)$ on the source $f$ are improved. Numerical experiments are presented to validate the theoretical findings, illustrating that the higher-order CIP-FEM can greatly reduce the pollution errors.

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具有高波数和完全匹配层截断的亥姆霍兹方程的高阶有限元和cip有限元

利用完全匹配层(PML)技术将整个空间上的高频亥姆霍兹方程截断为有界域，然后用高阶有限元法(FEM)和连续内罚有限元法(cipp -FEM)进行离散。通过构造与PML微分算子相关的有限个数特征函数线性组合的椭圆型问题，证明了PML问题的波数显式分解引理，表明PML解可以分解为非振荡椭圆部分和非振荡但解析部分。在$k^{2p+1}h^{2p}$足够小的网格条件下，证明了$p$-阶cipp -FEM和FEM的能量范数预渐近误差估计为$C_1(kh)^p +C_2k(kh)^{2p} +C_3 E^{\rm PML}$，其中$k$为波数，$h$为网格大小，$E^{\rm PML}$为指数小的PML截断误差。特别地，改进了系数$C_j~(j=1,2)$对源$f$的依赖性。数值实验验证了理论结果，表明采用高阶CIP-FEM可以大大降低污染误差。

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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arXiv - CS - Numerical Analysis

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