Convergence Analysis of Hybrid High-Order Methods for the Wave Equation

Erik Burman; Omar Duran; Alexandre Ern; Morgane Steins

doi:10.1007/s10915-021-01492-1

Convergence Analysis of Hybrid High-Order Methods for the Wave Equation

Erik Burman
, Omar Duran
, Alexandre Ern
, Morgane Steins

Research output: Contribution to journal › Article › peer-review

Abstract

We prove error estimates for the wave equation semi-discretized in space by the hybrid high-order (HHO) method. These estimates lead to optimal convergence rates for smooth solutions. We consider first the second-order formulation in time, for which we establish H¹ and L²-error estimates, and then the first-order formulation, for which we establish H¹-error estimates. For both formulations, the space semi-discrete HHO scheme has close links with hybridizable discontinuous Galerkin schemes from the literature. Numerical experiments using either the Newmark scheme or diagonally-implicit Runge–Kutta schemes for the time discretization illustrate the theoretical findings and show that the proposed numerical schemes can be used to simulate accurately the propagation of elastic waves in heterogeneous media.

Original language	English
Article number	91
Journal	Journal of Scientific Computing
Volume	87
Issue number	3
DOIs	https://doi.org/10.1007/s10915-021-01492-1
Publication status	Published - 1 Jun 2021

Keywords

Elastodynamics
Error analysis
Hybrid high-order methods
Wave equation

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10.1007/s10915-021-01492-1

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title = "Convergence Analysis of Hybrid High-Order Methods for the Wave Equation",

abstract = "We prove error estimates for the wave equation semi-discretized in space by the hybrid high-order (HHO) method. These estimates lead to optimal convergence rates for smooth solutions. We consider first the second-order formulation in time, for which we establish H1 and L2-error estimates, and then the first-order formulation, for which we establish H1-error estimates. For both formulations, the space semi-discrete HHO scheme has close links with hybridizable discontinuous Galerkin schemes from the literature. Numerical experiments using either the Newmark scheme or diagonally-implicit Runge–Kutta schemes for the time discretization illustrate the theoretical findings and show that the proposed numerical schemes can be used to simulate accurately the propagation of elastic waves in heterogeneous media.",

keywords = "Elastodynamics, Error analysis, Hybrid high-order methods, Wave equation",

author = "Erik Burman and Omar Duran and Alexandre Ern and Morgane Steins",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.",

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T1 - Convergence Analysis of Hybrid High-Order Methods for the Wave Equation

AU - Burman, Erik

AU - Duran, Omar

AU - Ern, Alexandre

AU - Steins, Morgane

PY - 2021/6/1

Y1 - 2021/6/1

N2 - We prove error estimates for the wave equation semi-discretized in space by the hybrid high-order (HHO) method. These estimates lead to optimal convergence rates for smooth solutions. We consider first the second-order formulation in time, for which we establish H1 and L2-error estimates, and then the first-order formulation, for which we establish H1-error estimates. For both formulations, the space semi-discrete HHO scheme has close links with hybridizable discontinuous Galerkin schemes from the literature. Numerical experiments using either the Newmark scheme or diagonally-implicit Runge–Kutta schemes for the time discretization illustrate the theoretical findings and show that the proposed numerical schemes can be used to simulate accurately the propagation of elastic waves in heterogeneous media.

AB - We prove error estimates for the wave equation semi-discretized in space by the hybrid high-order (HHO) method. These estimates lead to optimal convergence rates for smooth solutions. We consider first the second-order formulation in time, for which we establish H1 and L2-error estimates, and then the first-order formulation, for which we establish H1-error estimates. For both formulations, the space semi-discrete HHO scheme has close links with hybridizable discontinuous Galerkin schemes from the literature. Numerical experiments using either the Newmark scheme or diagonally-implicit Runge–Kutta schemes for the time discretization illustrate the theoretical findings and show that the proposed numerical schemes can be used to simulate accurately the propagation of elastic waves in heterogeneous media.

KW - Elastodynamics

KW - Error analysis

KW - Hybrid high-order methods

KW - Wave equation

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DO - 10.1007/s10915-021-01492-1

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SN - 0885-7474

VL - 87

JO - Journal of Scientific Computing

JF - Journal of Scientific Computing

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ER -

Convergence Analysis of Hybrid High-Order Methods for the Wave Equation

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