Comparative study of continuously differentiable Galerkin time discretizations for the wave equation

Bause, Markus; Anselmann, Mathias

doi:10.1002/pamm.201900144

Cited by 3 publications

(1 citation statement)

References 3 publications

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“…The conceptual basis of the families of approximations to the wave equation is the establishment of a connection between the Galerkin method for the time discretization and the classical collocation methods, with the perspective of achieving the accuracy of the former with reduced computational costs provided by the latter in terms of less complex algebraic systems. Further numerical studies for the wave equation can be found in [11,5]. For the application of the Galerkin-collocation to mathematical models of fluid flow and systems of ordinary differential equations we refer to [4,15,16].…”

Section: Introductionmentioning

confidence: 99%

$C^1$-conforming variational discretization of the biharmonic wave equation

Bause¹,

Lymbery²,

Osthues³

2021

Preprint

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Biharmonic wave equations are of importance to various applications including thin plate analyses. In this work, the numerical approximation of their solutions by a C 1 -conforming in space and time finite element approach is proposed and analyzed. Therein, the smoothness properties of solutions to the continuous evolution problem is embodied. High potential of the presented approach for more sophisticated multi-physics and multi-scale systems is expected. Time discretization is based on a combined Galerkin and collocation technique. For space discretization the Bogner-Fox-Schmit element is applied. Optimal order error estimates are proven. The convergence and performance properties are illustrated with numerical experiments.

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Section: Introductionmentioning

confidence: 99%

$C^1$-conforming variational discretization of the biharmonic wave equation

Bause¹,

Lymbery²,

Osthues³

2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

C1-conforming variational discretization of the biharmonic wave equation

Bause

Lymbery

Osthues

2022

Computers & Mathematics with Applications

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Galerkin–collocation approximation in time for the wave equation and its post-processing

et al. 2020

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We introduce and analyze families of Galerkin--collocation discretization schemes in time for the wave equation. Their conceptual basis is the establishment of a connection between the Galerkin method for the time discretization and the classical collocation methods, with the perspective of achieving the accuracy of the former with reduced computational costs provided by the latter in terms of less complex algebraic systems. Firstly, continuously differentiable in time discrete solutions are studied. Optimal order error estimates are proved. Then, the concept of Galerkin--collocation approximation is extended to twice continuously differentiable in time discrete solutions. A direct link between the two families by a computationally cheap post-processing is presented. A key ingredient of the proposed methods is the application of quadrature rules involving derivatives. The performance properties of the schemes are illustrated by numerical experiments.

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Comparative study of continuously differentiable Galerkin time discretizations for the wave equation

Cited by 3 publications

References 3 publications

$C^1$-conforming variational discretization of the biharmonic wave equation

$C^1$-conforming variational discretization of the biharmonic wave equation

C1-conforming variational discretization of the biharmonic wave equation

Galerkin–collocation approximation in time for the wave equation and its post-processing

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