A Two-Dimensional Stabilized Discontinuous Galerkin Method on Curvilinear Embedded Boundary Grids

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Andrew Giuliani

Published: Feb 1, 2022

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DOI Publisher

We propose a state redistribution method for high order discontinuous Galerkin methods on curvilinear embedded boundary grids. State redistribution relaxes the overly restrictive CFL condition that results from arbitrarily small cut cells and explicit time stepping. Thus, the scheme can take time steps that are proportional to the size of cells in the background grid. The discontinuous Galerkin scheme is stabilized b ...

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y postprocessing the numerical solution after each stage or step of an explicit time stepping method. This is done by temporarily merging the small cells into larger, possibly overlapping neighborhoods using a special weighted inner product. Then, the numerical solution on the neighborhoods is returned to the base grid in a conservative fashion. The advantage of this approach is that it uses only basic mesh information that is already available in many cut cell codes and does not require complex geometric manipulations. Finally, we present a number of test problems that demonstrate the encouraging potential of this technique for applications on curvilinear embedded geometries. Numerical experiments reveal that our scheme converges with order $p+1$ in $L_1$ and between $p$ and $p+1$ in $L_\infty$ for problems with smooth solutions. We also demonstrate that state redistribution is capable of capturing shocks.

Technical details

Canonical key: doi-10.1137_21m1396277

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Generated at: Apr 7, 2026, 2:38 AM

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We propose a state redistribution method for high order discontinuous Galerkin methods on curvilinear embedded boundary grids.

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Utility signals: depth 65/100, grounding 58/100, status medium.

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Last checked: Apr 7, 2026

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Tasks

Curvilinear coordinates, Grid, Discontinuous Galerkin method, Galerkin method, Numerical analysis, Boundary (topology), Boundary value problem, Mathematical analysis

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Domains

Mathematics, Applied mathematics

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