Optimal multilevel adaptive FEM for the Argyris element

The main drawback for the application of the conforming Argyris FEM is the labourious implementation on the one hand and the low convergence rates on the other. If no appropriate adaptive meshes are utilised, only the convergence rate caused by corner singularities [Blum and Rannacher, 1980], far be...

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Veröffentlicht in:	arXiv.org 2022-07
1. Verfasser:	Gräßle, Benedikt
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Sprache:	eng
Schlagworte:	Approximation Benchmarks Boundary conditions Computer Science - Numerical Analysis Convergence Finite element method Linear systems Mathematical analysis Mathematics - Numerical Analysis Rehabilitation Singularities Unstructured grids (mathematics)
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description	The main drawback for the application of the conforming Argyris FEM is the labourious implementation on the one hand and the low convergence rates on the other. If no appropriate adaptive meshes are utilised, only the convergence rate caused by corner singularities [Blum and Rannacher, 1980], far below the approximation order for smooth functions, can be achieved. The fine approximation with the Argyris FEM produces high-dimensional linear systems and for a long time an optimal preconditioned scheme was not available for unstructured grids. This paper presents numerical benchmarks to confirm that the adaptive multilevel solver for the hierarchical Argyris FEM from [Carstensen and Hu, 2021] is in fact highly efficient and of linear time complexity. Moreover, the very first display of optimal convergence rates in practically relevant benchmarks with corner singularities and general boundary conditions leads to the rehabilitation of the Argyris finite element from the computational perspective.
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subjects	Approximation Benchmarks Boundary conditions Computer Science - Numerical Analysis Convergence Finite element method Linear systems Mathematical analysis Mathematics - Numerical Analysis Rehabilitation Singularities Unstructured grids (mathematics)
title	Optimal multilevel adaptive FEM for the Argyris element
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