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Main Authors: Kuzmin, Dmitri, Lee, Sanghyun, Yang, Yi-Yung
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.19160
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author Kuzmin, Dmitri
Lee, Sanghyun
Yang, Yi-Yung
author_facet Kuzmin, Dmitri
Lee, Sanghyun
Yang, Yi-Yung
contents In this paper, we develop monolithic limiting techniques for enforcing nonlinear stability constraints in enriched Galerkin (EG) discretizations of nonlinear scalar hyperbolic equations. To achieve local mass conservation and gain control over the cell averages, the space of continuous (multi-)linear finite element approximations is enriched with piecewise-constant functions. The resulting spatial semi-discretization has the structure of a variational multiscale method. For linear advection equations, it is inherently stable but generally not bound preserving. To satisfy discrete maximum principles and ensure entropy stability in the nonlinear case, we use limiters adapted to the structure of our locally conservative EG method. The cell averages are constrained using a flux limiter, while the nodal values of the continuous component are constrained using a clip-and-scale limiting strategy for antidiffusive element contributions. The design and analysis of our new algorithms build on recent advances in the fields of convex limiting and algebraic entropy fixes for finite element methods. In addition to proving the claimed properties of the proposed approach, we conduct numerical studies for two-dimensional nonlinear hyperbolic problems. The numerical results demonstrate the ability of our limiters to prevent violations of the imposed constraints, while preserving the optimal order of accuracy in experiments with smooth solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2411_19160
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Bound-preserving and entropy stable enriched Galerkin methods for nonlinear hyperbolic equations
Kuzmin, Dmitri
Lee, Sanghyun
Yang, Yi-Yung
Numerical Analysis
76M10
In this paper, we develop monolithic limiting techniques for enforcing nonlinear stability constraints in enriched Galerkin (EG) discretizations of nonlinear scalar hyperbolic equations. To achieve local mass conservation and gain control over the cell averages, the space of continuous (multi-)linear finite element approximations is enriched with piecewise-constant functions. The resulting spatial semi-discretization has the structure of a variational multiscale method. For linear advection equations, it is inherently stable but generally not bound preserving. To satisfy discrete maximum principles and ensure entropy stability in the nonlinear case, we use limiters adapted to the structure of our locally conservative EG method. The cell averages are constrained using a flux limiter, while the nodal values of the continuous component are constrained using a clip-and-scale limiting strategy for antidiffusive element contributions. The design and analysis of our new algorithms build on recent advances in the fields of convex limiting and algebraic entropy fixes for finite element methods. In addition to proving the claimed properties of the proposed approach, we conduct numerical studies for two-dimensional nonlinear hyperbolic problems. The numerical results demonstrate the ability of our limiters to prevent violations of the imposed constraints, while preserving the optimal order of accuracy in experiments with smooth solutions.
title Bound-preserving and entropy stable enriched Galerkin methods for nonlinear hyperbolic equations
topic Numerical Analysis
76M10
url https://arxiv.org/abs/2411.19160