Your search keyword '"Worku, Zelalem A."' showing total 2 results

1. Entropy-split multidimensional summation-by-parts discretization of the Euler and compressible Navier-Stokes equations.

Author

Worku, Zelalem Arega and Zingg, David W.

Subjects

*NAVIER-Stokes equations, *EULER equations, *RUNGE-Kutta formulas, *MATRIX norms, *HEAT flux, *COMPRESSIBLE flow, *DISCRETIZATION methods

Abstract

High-order Hadamard-form entropy stable multidimensional summation-by-parts discretizations of the Euler and compressible Navier-Stokes equations are considerably more expensive than the standard divergence-form discretization. In search of a more efficient entropy stable scheme, we extend the entropy-split method for implementation on unstructured grids and investigate its properties. The main ingredients of the scheme are Harten's entropy functions, diagonal- E summation-by-parts operators with diagonal norm matrix, and entropy conservative simultaneous approximation terms (SATs). We show that the scheme is high-order accurate and entropy conservative on periodic curvilinear unstructured grids for the Euler equations. An entropy stable matrix-type interface dissipation operator is constructed, which can be added to the SATs to obtain an entropy stable semi-discretization. Fully-discrete entropy conservation is achieved using a relaxation Runge-Kutta method. Entropy stable viscous SATs, applicable to both the Hadamard-form and entropy-split schemes, are developed for the compressible Navier-Stokes equations. In the absence of heat fluxes, the entropy-split scheme is entropy stable for the compressible Navier-Stokes equations. Local conservation in the vicinity of discontinuities is enforced using an entropy stable hybrid scheme. Several numerical problems involving both smooth and discontinuous solutions are investigated to support the theoretical results. Computational cost comparison studies suggest that the entropy-split scheme offers substantial efficiency benefits relative to Hadamard-form multidimensional SBP-SAT discretizations. • Entropy-split scheme on unstructured grids using multidimensional SBP operators. • Entropy stable locally conservative hybrid discretization of the Euler equations. • Matrix-type artificial dissipation operator for Harten's entropy functions. • SATs for systems of equations with symmetric positive semidefinite diffusivity tensor. • Efficiency comparison of entropy-split and Hadamard-form SBP-SAT discretizations. [ABSTRACT FROM AUTHOR]

Published

2024

2. Simultaneous approximation terms and functional accuracy for diffusion problems discretized with multidimensional summation-by-parts operators.

Author

Worku, Zelalem Arega and Zingg, David W.

Subjects

*ELLIPTIC differential equations, *MATRIX norms, *DIOPHANTINE approximation, *SELFADJOINT operators

Abstract

Several types of simultaneous approximation term (SAT) for diffusion problems discretized with diagonal-norm multidimensional summation-by-parts (SBP) operators are analyzed based on a common framework. Conditions under which the SBP-SAT discretizations are consistent, conservative, adjoint consistent, and energy stable are presented. For SATs leading to primal and adjoint consistent discretizations, the error in output functionals is shown to be of order h 2 p when a degree p multidimensional SBP operator is used to discretize the spatial derivatives. SAT penalty coefficients corresponding to various discontinuous Galerkin fluxes developed for elliptic partial differential equations are identified. We demonstrate that the original method of Bassi and Rebay, the modified method of Bassi and Rebay, and the symmetric interior penalty method are equivalent when implemented with SBP diagonal-E operators that have diagonal norm matrix, e.g., the Legendre-Gauss-Lobatto SBP operator in one space dimension. Similarly, the local discontinuous Galerkin and the compact discontinuous Galerkin schemes are equivalent for this family of operators. The analysis remains valid on curvilinear grids if a degree ≤ p + 1 bijective polynomial mapping from the reference to physical elements is used. Numerical experiments with the two-dimensional Poisson problem support the theoretical results. • Simultaneous approximation terms for diffusion problems. • Adjoint consistency and functional superconvergence of SBP-SAT discretizations. • Equivalence of simultaneous approximation terms. • SBP-SAT discretization of second-order PDEs with multidimensional SBP operators. • Consistent, conservative, and energy stable SATs for elliptic problems. [ABSTRACT FROM AUTHOR]

Published

2021