FINITE-ELEMENT DOMAIN APPROXIMATION FOR MAXWELL VARIATIONAL PROBLEMS ON CURVED DOMAINS

Rubén Aylwin; Carlos Jerez-Hanckes

doi:10.1137/21M1468772

FINITE-ELEMENT DOMAIN APPROXIMATION FOR MAXWELL VARIATIONAL PROBLEMS ON CURVED DOMAINS

Rubén Aylwin, Carlos Jerez-Hanckes

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

2 Scopus citations

Abstract

We consider the problem of domain approximation in finite element methods for Maxwell equations on general curved domains, i.e., when affine or polynomial meshes fail to exactly cover the domain of interest and an exact parametrization of the surface may not be readily available. In such cases, one is forced to approximate the domain by a sequence of polyhedral domains arising from inexact mesh. We deduce conditions on the quality of these approximations that ensure rates of error convergence between discrete solutions-in the approximate domains-to the continuous one in the original domain. Moreover, we present numerical results validating our claims. Key words. Nédélec finite elements, curl-conforming elements, Maxwell equations, domain approximation, Strang lemma.

Original language	English
Pages (from-to)	1139-1171
Number of pages	33
Journal	SIAM Journal on Numerical Analysis
Volume	61
Issue number	3
DOIs	https://doi.org/10.1137/21M1468772
State	Published - 2023
Externally published	Yes

Keywords

Maxwell equations
Nédélec finite elements
Strang lemma
curl-conforming elements
domain approximation

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10.1137/21M1468772

Cite this

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title = "FINITE-ELEMENT DOMAIN APPROXIMATION FOR MAXWELL VARIATIONAL PROBLEMS ON CURVED DOMAINS",

abstract = "We consider the problem of domain approximation in finite element methods for Maxwell equations on general curved domains, i.e., when affine or polynomial meshes fail to exactly cover the domain of interest and an exact parametrization of the surface may not be readily available. In such cases, one is forced to approximate the domain by a sequence of polyhedral domains arising from inexact mesh. We deduce conditions on the quality of these approximations that ensure rates of error convergence between discrete solutions-in the approximate domains-to the continuous one in the original domain. Moreover, we present numerical results validating our claims. Key words. N{\'e}d{\'e}lec finite elements, curl-conforming elements, Maxwell equations, domain approximation, Strang lemma.",

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author = "Rub{\'e}n Aylwin and Carlos Jerez-Hanckes",

year = "2023",

doi = "10.1137/21M1468772",

language = "English",

volume = "61",

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T1 - FINITE-ELEMENT DOMAIN APPROXIMATION FOR MAXWELL VARIATIONAL PROBLEMS ON CURVED DOMAINS

AU - Aylwin, Rubén

AU - Jerez-Hanckes, Carlos

PY - 2023

Y1 - 2023

N2 - We consider the problem of domain approximation in finite element methods for Maxwell equations on general curved domains, i.e., when affine or polynomial meshes fail to exactly cover the domain of interest and an exact parametrization of the surface may not be readily available. In such cases, one is forced to approximate the domain by a sequence of polyhedral domains arising from inexact mesh. We deduce conditions on the quality of these approximations that ensure rates of error convergence between discrete solutions-in the approximate domains-to the continuous one in the original domain. Moreover, we present numerical results validating our claims. Key words. Nédélec finite elements, curl-conforming elements, Maxwell equations, domain approximation, Strang lemma.

AB - We consider the problem of domain approximation in finite element methods for Maxwell equations on general curved domains, i.e., when affine or polynomial meshes fail to exactly cover the domain of interest and an exact parametrization of the surface may not be readily available. In such cases, one is forced to approximate the domain by a sequence of polyhedral domains arising from inexact mesh. We deduce conditions on the quality of these approximations that ensure rates of error convergence between discrete solutions-in the approximate domains-to the continuous one in the original domain. Moreover, we present numerical results validating our claims. Key words. Nédélec finite elements, curl-conforming elements, Maxwell equations, domain approximation, Strang lemma.

KW - Maxwell equations

KW - Nédélec finite elements

KW - Strang lemma

KW - curl-conforming elements

KW - domain approximation

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ER -

FINITE-ELEMENT DOMAIN APPROXIMATION FOR MAXWELL VARIATIONAL PROBLEMS ON CURVED DOMAINS

Abstract

Keywords

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