Your search keyword '"Euler's equations"' showing total 3 results

1. A hybridizable discontinuous Galerkin formulation for the Euler–Maxwell plasma model.

Author

La Spina, Andrea and Fish, Jacob

Subjects

*TIME integration scheme, *GAUSS'S law (Electric fields), *EULER equations (Rigid dynamics), *ELECTROMAGNETIC coupling, *HYDRAULIC couplings

Abstract

This work introduces a hybridizable discontinuous Galerkin formulation for the simulation of ideal plasmas governed by the Euler–Maxwell equations. The approach is based on a monolithic source-based coupling of the fluid and electromagnetic subproblems, along with a fully implicit time integration scheme, and a projection-based divergence correction method to enforce the Gauss laws in challenging scenarios. The numerical examples demonstrate the high-order accuracy, efficiency, and robustness of the proposed formulation and validate it against problems of increasing complexity, ranging from single-physics cases to weakly and fully coupled electromagnetic plasma simulations. • Novel Hybridizable Discontinuous Galerkin formulation for Euler-Maxwell plasma model. • Monolithic source-based coupling and fully implicit time integration scheme. • Projection-based divergence correction method to enforce Gauss' laws. • Simulation of high-frequency plasma phenomena. • Accuracy, efficiency and robustness demonstrated on problems of increasing complexity. [ABSTRACT FROM AUTHOR]

Published

2024

2. Artificial boundary conditions for the numerical solution of the Euler equations by the discontinuous galerkin method

Author

Toulopoulos, Ioannis and Ekaterinaris, John A.

Subjects

*GALERKIN methods, *BOUNDARY value problems, *NUMERICAL analysis, *COMPUTER simulation, *FINITE element method, *VISCOUS flow

Abstract

Abstract: We present artificial boundary conditions for the numerical simulation of compressible flows using high-order accurate discretizations with the discontinuous Galerkin (DG) finite element method. The construction of the proposed boundary conditions is based on characteristic analysis and applied for boundaries with arbitrary shape and orientation. Numerical experiments demonstrate that the proposed boundary treatment enables to convect out of the computational domain complex flow features with little distortion. In addition, it is shown that small-amplitude acoustic disturbances could be convected out of the computational domain, with no significant deterioration of the overall accuracy of the method. Furthermore, it was found that application of the proposed boundary treatment for viscous flow over a cylinder yields superior performance compared to simple extrapolation methods. [Copyright &y& Elsevier]

Published

2011

3. Comparison of splitting algorithms for the rigid body

Author

Francesco Fassò

Subjects

Numerical Analysis, Physics and Astronomy (miscellaneous), Applied Mathematics, Moment of inertia, Rigid body dynamics, Rigid body, Computer Science Applications, Computational Mathematics, symbols.namesake, Modeling and Simulation, symbols, Special case, Hamiltonian (quantum mechanics), Euler's equations, Algorithm, Mathematics

Abstract

We compare several different second-order splitting algorithms for the asymmetric rigid body, with the aim of determining which one produces the smallest energy error for a given rigid body, namely, for given moments of inertia. The investigation is based on the analysis of the dominant term of the modified Hamiltonian and indicates that different algorithms can produce energy errors which differ by several orders of magnitude. As a byproduct of this analysis we remark that, for the special case of a flat rigid body with moments of inertia proportional to (1, 0.75, 0.25), one of the considered algorithms is in fact of order four.

Published

2003