A priori error estimates for the finite element approximation of westervelt's quasi-linear acoustic wave equation

Vanja Nikolić; Barbara Wohlmuth

doi:10.1137/19M1240873

A priori error estimates for the finite element approximation of westervelt's quasi-linear acoustic wave equation

Vanja Nikolić, Barbara Wohlmuth

Chair of Numerical Analysis

Technical University of Munich

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

17 Scopus citations

Abstract

We study the spatial discretization ofWestervelt's quasi-linear strongly damped wave equation by piecewise linear finite elements. Our approach employs the Banach fixed-point theorem combined with a priori analysis of a linear wave model with variable coefficients. Degeneracy of the semidiscrete Westervelt equation is avoided by relying on the inverse estimates for finite element functions and the stability and approximation properties of the interpolation operator. In this way, we obtain optimal convergence rates in L2-based spatial norms for sufficiently small data and mesh size and an appropriate choice of initial approximations. Numerical experiments in a setting of a one- dimensional channel as well as for a focused-ultrasound problem illustrate our theoretical findings.

Original language	English
Pages (from-to)	1897-1918
Number of pages	22
Journal	SIAM Journal on Numerical Analysis
Volume	57
Issue number	4
DOIs	https://doi.org/10.1137/19M1240873
State	Published - 2019

Keywords

A priori analysis
Finite element method
Nonlinear acoustics
Westervelt's equation

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abstract = "We study the spatial discretization ofWestervelt's quasi-linear strongly damped wave equation by piecewise linear finite elements. Our approach employs the Banach fixed-point theorem combined with a priori analysis of a linear wave model with variable coefficients. Degeneracy of the semidiscrete Westervelt equation is avoided by relying on the inverse estimates for finite element functions and the stability and approximation properties of the interpolation operator. In this way, we obtain optimal convergence rates in L2-based spatial norms for sufficiently small data and mesh size and an appropriate choice of initial approximations. Numerical experiments in a setting of a one- dimensional channel as well as for a focused-ultrasound problem illustrate our theoretical findings.",

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AU - Nikolić, Vanja

AU - Wohlmuth, Barbara

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N2 - We study the spatial discretization ofWestervelt's quasi-linear strongly damped wave equation by piecewise linear finite elements. Our approach employs the Banach fixed-point theorem combined with a priori analysis of a linear wave model with variable coefficients. Degeneracy of the semidiscrete Westervelt equation is avoided by relying on the inverse estimates for finite element functions and the stability and approximation properties of the interpolation operator. In this way, we obtain optimal convergence rates in L2-based spatial norms for sufficiently small data and mesh size and an appropriate choice of initial approximations. Numerical experiments in a setting of a one- dimensional channel as well as for a focused-ultrasound problem illustrate our theoretical findings.

AB - We study the spatial discretization ofWestervelt's quasi-linear strongly damped wave equation by piecewise linear finite elements. Our approach employs the Banach fixed-point theorem combined with a priori analysis of a linear wave model with variable coefficients. Degeneracy of the semidiscrete Westervelt equation is avoided by relying on the inverse estimates for finite element functions and the stability and approximation properties of the interpolation operator. In this way, we obtain optimal convergence rates in L2-based spatial norms for sufficiently small data and mesh size and an appropriate choice of initial approximations. Numerical experiments in a setting of a one- dimensional channel as well as for a focused-ultrasound problem illustrate our theoretical findings.

KW - A priori analysis

KW - Finite element method

KW - Nonlinear acoustics

KW - Westervelt's equation

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JO - SIAM Journal on Numerical Analysis

JF - SIAM Journal on Numerical Analysis

IS - 4

ER -

A priori error estimates for the finite element approximation of westervelt's quasi-linear acoustic wave equation

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Keywords

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