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Spectral analysis of continuous FEM for hyperbolic PDEs: Influence of approximation, stabilization, and time-stepping

Michel, Sixtine; Torlo, Davide; Ricchiuto, Mario; Abgrall, Remi (2021). Spectral analysis of continuous FEM for hyperbolic PDEs: Influence of approximation, stabilization, and time-stepping. Journal of Scientific Computing, 89(2):31.

Abstract

We study continuous finite element dicretizations for one dimensional hyperbolic partial differential equations. The main contribution of the paper is to provide a fully discrete spectral analysis, which is used to suggest optimal values of the CFL number and of the stabilization parameters involved in different types of stabilization operators. In particular, we analyze the streamline-upwind Petrov–Galerkin stabilization technique, the continuous interior penalty (CIP) stabilization method and the orthogonal subscale stabilization (OSS). Three different choices for the continuous finite element space are compared: Bernstein polynomials, Lagrangian polynomials on equispaced nodes, and Lagrangian polynomials on Gauss-Lobatto cubature nodes. For the last choice, we only consider inexact quadrature based on the formulas corresponding to the degrees of freedom of the element, which allows to obtain a fully diagonal mass matrix. We also compare different time stepping strategies, namely Runge–Kutta (RK), strong stability preserving RK (SSPRK) and deferred correction time integration methods. The latter allows to alleviate the computational cost as the mass matrix inversion is replaced by the high order correction iterations. To understand the effects of these choices, both time-continuous and fully discrete Fourier analysis are performed. These allow to compare all the different combinations in terms of accuracy and stability, as well as to provide suggestions for optimal values discretization parameters involved. The results are thoroughly verified numerically both on linear and non-linear problems, and error-CPU time curves are provided. Our final conclusions suggest that cubature elements combined with SSPRK and CIP or OSS stabilization are the most promising combinations.

Additional indexing

Item Type:Journal Article, refereed, original work
Communities & Collections:07 Faculty of Science > Institute of Mathematics
Dewey Decimal Classification:340 Law
610 Medicine & health
510 Mathematics
Scopus Subject Areas:Physical Sciences > Software
Physical Sciences > Theoretical Computer Science
Physical Sciences > Numerical Analysis
Physical Sciences > General Engineering
Physical Sciences > Computational Theory and Mathematics
Physical Sciences > Computational Mathematics
Physical Sciences > Applied Mathematics
Uncontrolled Keywords:Computational Theory and Mathematics, General Engineering, Theoretical Computer Science, Software, Applied Mathematics, Computational Mathematics, Numerical Analysis
Language:English
Date:1 November 2021
Deposited On:04 Nov 2021 12:49
Last Modified:26 Dec 2024 02:37
Publisher:Springer
ISSN:0885-7474
OA Status:Closed
Publisher DOI:https://doi.org/10.1007/s10915-021-01632-7
Project Information:
  • Funder: Conseil Régional Aquitaine
  • Grant ID:
  • Project Title:
  • Funder: SNSF
  • Grant ID: 200020_175784
  • Project Title: Solving advection dominated problems with high order schemes with polygonal meshes: application to compressible and incompressible flow problems
  • Funder: SNSF
  • Grant ID: 200020_175784
  • Project Title: Solving advection dominated problems with high order schemes with polygonal meshes: application to compressible and incompressible flow problems

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