An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems

An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems

We present a new, optimally accurate finite element method for interface problems that does not require matching interface grids or spatially coincident interfaces. The key idea is to enforce “extended” interface conditions through pullbacks onto the discretized interfaces. In so doing our approach...

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Main Authors: James Cheung, Max Gunzburger, Pavel Bochev, Mauro Perego
Format: Article
Language:English
Published: Elsevier 2020-05-01
Series:Results in Applied Mathematics
Online Access:http://www.sciencedirect.com/science/article/pii/S2590037420300042
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spelling doaj-9224e8eabd064eb9ab9c96028adfef2d2020-11-25T02:39:03ZengElsevierResults in Applied Mathematics2590-03742020-05-016An optimally convergent higher-order finite element coupling method for interface and domain decomposition problemsJames Cheung0Max Gunzburger1Pavel Bochev2Mauro Perego3Interdisciplinary Center for Applied Mathematics, Virginia Tech, Blacksburg, VA, 24061, United States of AmericaDepartment of Scientific Computing, Florida State University, Tallahassee, FL, 32304, United States of AmericaCenter for Computing Research, Sandia National Laboratories, Mail Stop 1320, Albuquerque, NM, 87185-1320, United States of America; Corresponding author.Department of Scientific Computing, Florida State University, Tallahassee, FL, 32304, United States of AmericaWe present a new, optimally accurate finite element method for interface problems that does not require matching interface grids or spatially coincident interfaces. The key idea is to enforce “extended” interface conditions through pullbacks onto the discretized interfaces. In so doing our approach circumvents the accuracy barriers prompted by polytopial approximations of the subdomains and enables high-order finite element solutions without needing more expensive curvilinear maps. Since the discrete interfaces are not required to match, the approach is also appropriate for multiphysics couplings where each subdomain is meshed independently and solved by a separate code. Error analysis reveals that the new approach is well posed and optimally convergent with respect to a broken H1norm. Numerical examples confirm this result and also indicate optimal convergence in a broken L2norm.http://www.sciencedirect.com/science/article/pii/S2590037420300042
collection DOAJ
language English
format Article
sources DOAJ
author James Cheung
Max Gunzburger
Pavel Bochev
Mauro Perego
spellingShingle James Cheung
Max Gunzburger
Pavel Bochev
Mauro Perego
An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
Results in Applied Mathematics
author_facet James Cheung
Max Gunzburger
Pavel Bochev
Mauro Perego
author_sort James Cheung
title An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
title_short An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
title_full An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
title_fullStr An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
title_full_unstemmed An optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
title_sort optimally convergent higher-order finite element coupling method for interface and domain decomposition problems
publisher Elsevier
series Results in Applied Mathematics
issn 2590-0374
publishDate 2020-05-01
description We present a new, optimally accurate finite element method for interface problems that does not require matching interface grids or spatially coincident interfaces. The key idea is to enforce “extended” interface conditions through pullbacks onto the discretized interfaces. In so doing our approach circumvents the accuracy barriers prompted by polytopial approximations of the subdomains and enables high-order finite element solutions without needing more expensive curvilinear maps. Since the discrete interfaces are not required to match, the approach is also appropriate for multiphysics couplings where each subdomain is meshed independently and solved by a separate code. Error analysis reveals that the new approach is well posed and optimally convergent with respect to a broken H1norm. Numerical examples confirm this result and also indicate optimal convergence in a broken L2norm.
url http://www.sciencedirect.com/science/article/pii/S2590037420300042
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