Analysis of a high-order unfitted finite element method for elliptic interface problems

Lehrenfeld, Christoph; Reusken, Arnold

doi:10.1093/imanum/drx041

Cited by 56 publications

(90 citation statements)

References 48 publications

(92 reference statements)

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“…so that n T (V, V ) ≥ 1 2 (ξ 2 + ζ 2 ) (i.e., (26)) follows from the assumption that η ≥ 4c 2 dtr . Moreover, using the Cauchy-Schwarz inequality, we infer that…”

Section: Stability and Well-posednessmentioning

confidence: 99%

“…The so-called cutFEM framework was developed recently in [8] so as to couple different physical models over unfitted interfaces and to discretize PDEs over unfitted embedded submanifolds. The high-order approximation of the geometry of the interface was considered recently in [10] using a boundary correction based on local Taylor expansions and in [26] using an iso-parametric technique, the common objective being to simplify the numerical integration on domains with curved boundaries by allowing a piecewise affine representation of the interface. The cutFEM paradigm has also been applied to a variety of complex flow problems, see, e.g., [27], the recent PhD thesis [30], and references therein.…”

Section: Introductionmentioning

confidence: 99%

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An Unfitted Hybrid High-Order Method for Elliptic Interface Problems

Burman¹,

Ern²

2018

SIAM J. Numer. Anal.

106

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We design and analyze a Hybrid High-Order (HHO) method on unfitted meshes to approximate elliptic interface problems. The curved interface can cut through the mesh cells in a very general fashion. As in classical HHO methods, the present unfitted method introduces cell and face unknowns in uncut cells, but doubles the unknowns in the cut cells and on the cut faces. The main difference with classical HHO methods is that a Nitsche-type formulation is used to devise the local reconstruction operator. As in classical HHO methods, cell unknowns can be eliminated locally leading to a global problem coupling only the face unknowns by means of a compact stencil. We prove stability estimates and optimal error estimates in the H 1 -norm. Robustness with respect to cuts is achieved by a local cell-agglomeration procedure taking full advantage of the fact that HHO methods support polyhedral meshes. Robustness with respect to the contrast in the material properties from both sides of the interface is achieved by using material-dependent weights in Nitsche's formulation.

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“…so that n T (V, V ) ≥ 1 2 (ξ 2 + ζ 2 ) (i.e., (26)) follows from the assumption that η ≥ 4c 2 dtr . Moreover, using the Cauchy-Schwarz inequality, we infer that…”

Section: Stability and Well-posednessmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Unfitted Hybrid High-Order Method for Elliptic Interface Problems

Burman¹,

Ern²

2018

SIAM J. Numer. Anal.

106

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show abstract

“…In this regard, developing techniques dedicated to boundary conditions which are prescribed on curved boundaries is of paramount importance to achieve high‐order accurate convergence. The classical technique is based on the isoparametric elements method, but similar techniques have been specifically designed for the finite volume method. For example, the seminal paper of Ollivier‐Gooch and Van Altena introduces a technique to handle smooth curved boundaries based on the constrained least‐squares method for the boundary edges.…”

Section: Curved Boundary Treatmentmentioning

confidence: 99%

“…For a short literature review on the topic, the reader is referred to the introduction section in the work of Costa et al, which is summarized in the following. The classical approach to handle with curved boundary conditions is based on the isoparametric element method, which requires, on one side, the introduction of curved mesh elements, and on the other side, nonlinear transformations to map the local curved mesh elements onto the reference polygonal ones. An alternative approach, dedicated to the finite volume method, was initially proposed by Ollivier‐Gooch and Van Altena .…”

Section: Introductionmentioning

confidence: 99%

Very high‐order accurate finite volume scheme for the convection‐diffusion equation with general boundary conditions on arbitrary curved boundaries

Costa

Nóbrega

Clain

et al. 2018

Numerical Meth Engineering

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Summary Obtaining very high‐order accurate solutions in curved domains is a challenging task as the accuracy of discretization methods may dramatically reduce without an appropriate treatment of boundary conditions. The classical techniques to preserve the nominal convergence order of accuracy, proposed in the context of finite element and finite volume methods, rely on curved mesh elements, which fit curved boundaries. Such techniques often demand sophisticated meshing algorithms, cumbersome quadrature rules for integration, and complex nonlinear transformations to map the curved mesh elements onto the reference polygonal ones. In this regard, the reconstruction for off‐site data method, proposed in the work of Costa et al, provides very high‐order accurate polynomial reconstructions on arbitrary smooth curved boundaries, enabling integration of the governing equations on polygonal mesh elements, and therefore, avoiding the use of complex integration quadrature rules or nonlinear transformations. The method was introduced for Dirichlet boundary conditions and the present article proposes an extension for general boundary conditions, which represents an important advance for real context applications. A generic framework to compute polynomial reconstructions is also developed based on the least‐squares method, which handles general constraints and further improves the algorithm. The proposed methods are applied to solve the convection‐diffusion equation with a finite volume discretization in unstructured meshes. A comprehensive numerical benchmark test suite is provided to verify and assess the accuracy, convergence orders, robustness, and efficiency, which proves that boundary conditions on arbitrary smooth curved boundaries are properly fulfilled and the nominal very high‐order convergence orders are effectively achieved.

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“…The major difficulty in the analysis is to estimate the error coming from the curved interface replaced by a discrete one. Note that, more recently Lehrenfeld and Reusken also considered the geometry error for unfitted methods. In that article, the interface was discretized by the corresponding level set function which is different from that of our method.…”

Section: Introductionmentioning

confidence: 99%

Unfitted finite element methods for the heat conduction in composite media with contact resistance

Wang

Chen

2016

Numerical Methods Partial

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This article is concerned with the heat conduction problem in composite media. In practical applications, the composite materials often do not contact well and there exist gaps between the contacting materials. This leads to the thermal contact resistance effect which results in a discontinuity of the temperature across the interface. In this article, an unfitted finite element method is proposed to solve the problem. Different from the traditional finite element method, the proposed method uses structured meshes that allow the interface to cut through. To avoid integrating on curved domains and interfaces, the interface is approximated by a broken line/plane corresponding to the triangulation. In addition, a ghost‐penalty is added to recover the condition number of the stiffness matrix to O ( h − 2 ) with a hidden constant independent of the mesh‐interface geometry. A rigorous analysis is provided. Finally, numerical tests are presented to verify the theoretical findings. © 2016 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 33: 354–380, 2017

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Analysis of a high-order unfitted finite element method for elliptic interface problems

Cited by 56 publications

References 48 publications

An Unfitted Hybrid High-Order Method for Elliptic Interface Problems

An Unfitted Hybrid High-Order Method for Elliptic Interface Problems

Very high‐order accurate finite volume scheme for the convection‐diffusion equation with general boundary conditions on arbitrary curved boundaries

Unfitted finite element methods for the heat conduction in composite media with contact resistance

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