Towards a geometric variational discretization of compressible fluids: The rotating shallow water equations

Werner Bauer; François Gay-Balmaz

doi:10.3934/jcd.2019001

Towards a geometric variational discretization of compressible fluids: The rotating shallow water equations

Werner Bauer
, François Gay-Balmaz

Research output: Contribution to journal › Article › peer-review

Abstract

This paper presents a geometric variational discretization of com- pressible uid dynamics. The numerical scheme is obtained by discretizing, in a structure preserving way, the Lie group formulation of uid dynamics on dif- feomorphism groups and the associated variational principles. Our framework applies to irregular mesh discretizations in 2D and 3D. It systematically ex- tends work previously made for incompressible uids to the compressible case. We consider in detail the numerical scheme on 2D irregular simplicial meshes and evaluate the scheme numerically for the rotating shallow water equations. In particular, we investigate whether the scheme conserves stationary solutions, represents well the nonlinear dynamics, and approximates well the frequency relations of the continuous equations, while preserving conservation laws such as mass and total energy.

Original language	English
Pages (from-to)	1-37
Number of pages	37
Journal	Journal of Computational Dynamics
Volume	6
Issue number	1
DOIs	https://doi.org/10.3934/jcd.2019001
Publication status	Published - 1 Jan 2019

Keywords

Euler-Poincaré formulation
Geometric discretization
Rotating shallow water equations
Structure-preserving schemes
uid dynam- ics

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10.3934/jcd.2019001

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abstract = "This paper presents a geometric variational discretization of com- pressible uid dynamics. The numerical scheme is obtained by discretizing, in a structure preserving way, the Lie group formulation of uid dynamics on dif- feomorphism groups and the associated variational principles. Our framework applies to irregular mesh discretizations in 2D and 3D. It systematically ex- tends work previously made for incompressible uids to the compressible case. We consider in detail the numerical scheme on 2D irregular simplicial meshes and evaluate the scheme numerically for the rotating shallow water equations. In particular, we investigate whether the scheme conserves stationary solutions, represents well the nonlinear dynamics, and approximates well the frequency relations of the continuous equations, while preserving conservation laws such as mass and total energy.",

keywords = "Euler-Poincar{\'e} formulation, Geometric discretization, Rotating shallow water equations, Structure-preserving schemes, uid dynam- ics",

author = "Werner Bauer and Fran{\c c}ois Gay-Balmaz",

note = "Publisher Copyright: {\textcopyright} American Institute of Mathematical Sciences.",

year = "2019",

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AU - Bauer, Werner

AU - Gay-Balmaz, François

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N2 - This paper presents a geometric variational discretization of com- pressible uid dynamics. The numerical scheme is obtained by discretizing, in a structure preserving way, the Lie group formulation of uid dynamics on dif- feomorphism groups and the associated variational principles. Our framework applies to irregular mesh discretizations in 2D and 3D. It systematically ex- tends work previously made for incompressible uids to the compressible case. We consider in detail the numerical scheme on 2D irregular simplicial meshes and evaluate the scheme numerically for the rotating shallow water equations. In particular, we investigate whether the scheme conserves stationary solutions, represents well the nonlinear dynamics, and approximates well the frequency relations of the continuous equations, while preserving conservation laws such as mass and total energy.

AB - This paper presents a geometric variational discretization of com- pressible uid dynamics. The numerical scheme is obtained by discretizing, in a structure preserving way, the Lie group formulation of uid dynamics on dif- feomorphism groups and the associated variational principles. Our framework applies to irregular mesh discretizations in 2D and 3D. It systematically ex- tends work previously made for incompressible uids to the compressible case. We consider in detail the numerical scheme on 2D irregular simplicial meshes and evaluate the scheme numerically for the rotating shallow water equations. In particular, we investigate whether the scheme conserves stationary solutions, represents well the nonlinear dynamics, and approximates well the frequency relations of the continuous equations, while preserving conservation laws such as mass and total energy.

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KW - Structure-preserving schemes

KW - uid dynam- ics

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Towards a geometric variational discretization of compressible fluids: The rotating shallow water equations

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