Space-time unfitted finite elements on moving explicit geometry representations

This work proposes a novel variational approximation of partial differential equations on moving geometries determined by explicit boundary representations. The benefits of the proposed formulation are the ability to handle large displacements of explicitly represented domain boundaries without gene...

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Bibliographic Details
Published inarXiv.org
Main Authors Badia, Santiago, Martorell, Pere A, Verdugo, Francesc
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 23.05.2024
Subjects
Algorithms
Boundary representation
Computer Science - Computational Engineering, Finance, and Science
Computer Science - Numerical Analysis
Deformation
Differential geometry
Intersections
Mathematical analysis
Mathematics - Numerical Analysis
Operators (mathematics)
Partial differential equations
Rotating fluids
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Summary:This work proposes a novel variational approximation of partial differential equations on moving geometries determined by explicit boundary representations. The benefits of the proposed formulation are the ability to handle large displacements of explicitly represented domain boundaries without generating body-fitted meshes and remeshing techniques. For the space discretization, we use a background mesh and an unfitted method that relies on integration on cut cells only. We perform this intersection by using clipping algorithms. To deal with the mesh movement, we pullback the equations to a reference configuration (the spatial mesh at the initial time slab times the time interval) that is constant in time. This way, the geometrical intersection algorithm is only required in 3D, another key property of the proposed scheme. At the end of the time slab, we compute the deformed mesh, intersect the deformed boundary with the background mesh, and consider an exact transfer operator between meshes to compute jump terms in the time discontinuous Galerkin integration. The transfer is also computed using geometrical intersection algorithms. We demonstrate the applicability of the method to fluid problems around rotating (2D and 3D) geometries described by oriented boundary meshes. We also provide a set of numerical experiments that show the optimal convergence of the method.
ISSN:2331-8422
DOI:10.48550/arxiv.2401.12649