Geometrical discretisations for unfitted finite elements on explicit boundary representations

S. Badia; P.A. Martorell; F. Verdugo

doi:10.1016/j.jcp.2022.111162

Geometrical discretisations for unfitted finite elements on explicit boundary representations

S. Badia, P.A. Martorell, F. Verdugo

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

© 2022 Elsevier Inc.Unfitted (also known as embedded or immersed) finite element approximations of partial differential equations are very attractive because they have much lower geometrical requirements than standard body-fitted formulations. These schemes do not require body-fitted unstructured mesh generation. In turn, the numerical integration becomes more involved, because one has to compute integrals on portions of cells (only the interior part). In practice, these methods are restricted to level-set (implicit) geometrical representations, which drastically limit their application. Complex geometries in industrial and scientific problems are usually determined by (explicit) boundary representations. In this work, we propose an automatic computational framework for the discretisation of partial differential equations on domains defined by oriented boundary meshes. The geometrical kernel that connects functional and geometry representations generates a two-level integration mesh and a refinement of the boundary mesh that enables the straightforward numerical integration of all the terms in unfitted finite elements. The proposed framework has been applied with success on all analysis-suitable oriented boundary meshes (almost 5,000) in the Thingi10K database and combined with an unfitted finite element formulation to discretise partial differential equations on the corresponding domains.

Original language	English
Article number	111162
Journal	Journal of Computational Physics
Volume	460
DOIs	https://doi.org/10.1016/j.jcp.2022.111162
Publication status	Published - 1 Jul 2022
Externally published	Yes

Funding

This research was partially funded by the Australian Government through the Australian Research Council (project number DP210103092 ), the European Commission under the FET-HPC ExaQUte project (Grant agreement ID: 800898 ) within the Horizon 2020 Framework Programme and the project RTI2018-096898-B-I00 from the “FEDER/ Ministerio de Ciencia e Innovación – Agencia Estatal de Investigación”. F. Verdugo acknowledges support from the Spanish Ministry of Economy and Competitiveness through the “Severo Ochoa Programme for Centers of Excellence in R&D ( CEX2018-000797-S )”. P.A. Martorell acknowledges the support received from Universitat Politècnica de Catalunya and Santander Bank through an FPI fellowship ( FPI-UPC 2019 ). This work was also supported by computational resources provided by the Australian Government through NCI under the National Computational Merit Allocation Scheme. This research was partially funded by the Australian Government through the Australian Research Council (project number DP210103092), the European Commission under the FET-HPC ExaQUte project (Grant agreement ID: 800898) within the Horizon 2020 Framework Programme and the project RTI2018-096898-B-I00 from the ?FEDER/Ministerio de Ciencia e Innovaci?n ? Agencia Estatal de Investigaci?n?. F. Verdugo acknowledges support from the Spanish Ministry of Economy and Competitiveness through the ?Severo Ochoa Programme for Centers of Excellence in R&D (CEX2018-000797-S)?. P.A. Martorell acknowledges the support received from Universitat Polit?cnica de Catalunya and Santander Bank through an FPI fellowship (FPI-UPC 2019). This work was also supported by computational resources provided by the Australian Government through NCI under the National Computational Merit Allocation Scheme.

Funders	Funder number
Santander Bank	FPI-UPC 2019
Universitat Polit?cnica de Catalunya
National Computational Infrastructure
Horizon 2020 Framework Programme	RTI2018-096898-B-I00, 800898
Australian Government
European Commission
Australian Research Council	DP210103092
Ministerio de Economía y Competitividad	CEX2018-000797-S
Ministerio de Ciencia e Innovación
Agencia Estatal de Investigación
Universitat Politècnica de Catalunya

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abstract = "{\textcopyright} 2022 Elsevier Inc.Unfitted (also known as embedded or immersed) finite element approximations of partial differential equations are very attractive because they have much lower geometrical requirements than standard body-fitted formulations. These schemes do not require body-fitted unstructured mesh generation. In turn, the numerical integration becomes more involved, because one has to compute integrals on portions of cells (only the interior part). In practice, these methods are restricted to level-set (implicit) geometrical representations, which drastically limit their application. Complex geometries in industrial and scientific problems are usually determined by (explicit) boundary representations. In this work, we propose an automatic computational framework for the discretisation of partial differential equations on domains defined by oriented boundary meshes. The geometrical kernel that connects functional and geometry representations generates a two-level integration mesh and a refinement of the boundary mesh that enables the straightforward numerical integration of all the terms in unfitted finite elements. The proposed framework has been applied with success on all analysis-suitable oriented boundary meshes (almost 5,000) in the Thingi10K database and combined with an unfitted finite element formulation to discretise partial differential equations on the corresponding domains.",

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AB - © 2022 Elsevier Inc.Unfitted (also known as embedded or immersed) finite element approximations of partial differential equations are very attractive because they have much lower geometrical requirements than standard body-fitted formulations. These schemes do not require body-fitted unstructured mesh generation. In turn, the numerical integration becomes more involved, because one has to compute integrals on portions of cells (only the interior part). In practice, these methods are restricted to level-set (implicit) geometrical representations, which drastically limit their application. Complex geometries in industrial and scientific problems are usually determined by (explicit) boundary representations. In this work, we propose an automatic computational framework for the discretisation of partial differential equations on domains defined by oriented boundary meshes. The geometrical kernel that connects functional and geometry representations generates a two-level integration mesh and a refinement of the boundary mesh that enables the straightforward numerical integration of all the terms in unfitted finite elements. The proposed framework has been applied with success on all analysis-suitable oriented boundary meshes (almost 5,000) in the Thingi10K database and combined with an unfitted finite element formulation to discretise partial differential equations on the corresponding domains.

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Geometrical discretisations for unfitted finite elements on explicit boundary representations

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