首页|Analysis of transient wave propagation dynamics using the enriched finite element method with interpolation cover functions

Analysis of transient wave propagation dynamics using the enriched finite element method with interpolation cover functions

扫码查看
原文链接
  • NSTL
  • Elsevier
To improve the performance of the low-order linear triangular element for solving transient wave propagation problems, this paper presents a novel enriched finite element method (EFEM) for wave analysis. The original linear nodal shape functions are enriched by using the additional interpolation cover functions over patches of elements. To effectively solve the wave problems, the used interpolation cover function is constructed by using the Lagrangian functions plus the harmonic trigonometric functions. The present approach can be regarded as a combination of the classical finite elements and the spectral techniques, but individual strengths of the two methods are synergized, so more accurate results can be obtained compared to the standard finite elements. In this work the root of the linear dependence (LD) issue in the present EFEM is investigated detailedly, and then an effective approach is proposed to completely eliminate the LD problem. By performing the dispersion analysis, it is found that the present EFEM possesses the attractive monotonic convergence property for transient wave propagations, that is the obtained numerical solutions will monotonically converge to the exact solutions with the decreasing time steps for time integration as long as the reasonably fine meshes are used. Several typical numerical examples are solved to illustrate the capacities of the present method. (C) 2021 Elsevier Inc. All rights reserved.

Wave propagationInterpolation cover functionsTime integrationEnriched finite elementsNumerical methodsGRADIENT SMOOTHING TECHNIQUEBOUNDARY-ELEMENTHELMHOLTZ-EQUATIONFUNDAMENTAL-SOLUTIONSACOUSTIC RADIATIONPARTITIONOPTIMIZATIONDIFFUSIONARBITRARYMODEL

Chai, Yingbin、Li, Wei、Liu, Zuyuan

展开 >

Wuhan Univ Technol

Huazhong Univ Sci & Technol

2022

10.1016/j.amc.2021.126564

Applied mathematics and computation

Applied mathematics and computation

EISCI
ISSN:0096-3003
年,卷(期):2022.412
  • 40
  • 71