Your search keyword '"Andrew R. Winters"' showing total 6 results

1. Affordable, entropy conserving and entropy stable flux functions for the ideal MHD equations

Author

Andrew R. Winters and Gregor J. Gassner

Subjects

Physics and Astronomy (miscellaneous), Beräkningsmatematik, Configuration entropy, finite volume method, ideal MHD equations, 010103 numerical & computational mathematics, 01 natural sciences, entropy stable, Entropy stability, FOS: Mathematics, Applied mathematics, Mathematics - Numerical Analysis, Numerical tests, 0101 mathematics, Mathematics, Numerical Analysis, Finite volume method, Applied Mathematics, Mathematical analysis, Computational mathematics, Numerical Analysis (math.NA), nonlinear hyperbolic conservation law, Dissipation, Computer Science Applications, 010101 applied mathematics, Computational Mathematics, Modeling and Simulation, entropy conservation, Magnetohydrodynamics, Entropy conservation

Abstract

In this work, we design an entropy stable, finite volume approximation for the ideal magnetohydrodynamics (MHD) equations. The method is novel as we design an affordable analytical expression of the numerical interface flux function that discretely preserves the entropy of the system. To guarantee the discrete conservation of entropy requires the addition of a particular source term to the ideal MHD system. Exact entropy conserving schemes cannot dissipate energy at shocks, thus to compute accurate solutions to problems that may develop shocks, we determine a dissipation term to guarantee entropy stability for the numerical scheme. Numerical tests are performed to demonstrate the theoretical findings of entropy conservation and robustness., arXiv admin note: substantial text overlap with arXiv:1509.06902; text overlap with arXiv:1007.2606 by other authors

Published

2016

2. Ideal GLM-MHD: About the entropy consistent nine-wave magnetic field divergence diminishing ideal magnetohydrodynamics equations

Author

Andrew R. Winters, Stefanie Walch, Dominik Derigs, Gregor J. Gassner, and Marvin Bohm

Subjects

Other Physics Topics, Physics and Astronomy (miscellaneous), Beräkningsmatematik, media_common.quotation_subject, entropy stability, FOS: Physical sciences, Second law of thermodynamics, 010103 numerical & computational mathematics, divergence-free magnetic field, 01 natural sciences, FOS: Mathematics, Fluid dynamics, Mathematics - Numerical Analysis, divergence cleaning, 0101 mathematics, media_common, Mathematics, Numerical Analysis, Computer simulation, Adaptive mesh refinement, Applied Mathematics, Mathematical analysis, Computational mathematics, Annan fysik, Numerical Analysis (math.NA), Computational Physics (physics.comp-ph), Solver, 3. Good health, Computer Science Applications, Magnetic field, 010101 applied mathematics, Computational Mathematics, Modeling and Simulation, Magnetohydrodynamics, magnetohydrodynamics, Physics - Computational Physics

Abstract

The paper presents two contributions in the context of the numerical simulation of magnetized fluid dynamics. First, we show how to extend the ideal magnetohydrodynamics (MHD) equations with an inbuilt magnetic field divergence cleaning mechanism in such a way that the resulting model is consistent with the second law of thermodynamics. As a byproduct of these derivations, we show that not all of the commonly used divergence cleaning extensions of the ideal MHD equations are thermodynamically consistent. Secondly, we present a numerical scheme obtained by constructing a specific finite volume discretization that is consistent with the discrete thermodynamic entropy. It includes a mechanism to control the discrete divergence error of the magnetic field by construction and is Galilean invariant. We implement the new high-order MHD solver in the adaptive mesh refinement code FLASH where we compare the divergence cleaning efficiency to the constrained transport solver available in FLASH (unsplit staggered mesh scheme)., Comment: 54 pages

Published

2018

3. ALE-DGSEM approximation of wave reflection and transmission from a moving medium

Author

David A. Kopriva and Andrew R. Winters

Subjects

Numerical Analysis, Conservation law, Physics and Astronomy (miscellaneous), Applied Mathematics, Mathematical analysis, Plane wave, Wave equation, Computer Science Applications, Computational Mathematics, symbols.namesake, Classical mechanics, Riemann problem, Transmission (telecommunications), Discontinuous Galerkin method, Modeling and Simulation, symbols, Reflection (physics), Material properties, Mathematics

Abstract

We derive a spectrally accurate moving mesh method for mixed material interface problems modeled by Maxwell's or the classical wave equation. We use a discontinuous Galerkin spectral element approximation with an arbitrary Lagrangian-Eulerian mapping and derive the exact upwind numerical fluxes to model the physics of wave reflection and transmission at jumps in material properties. Spectral accuracy is obtained by placing moving material interfaces at element boundaries and solving the appropriate Riemann problem. We present numerical examples showing the performance of the method for plane wave reflection and transmission at dielectric and acoustic interfaces.

Published

2014

4. A novel averaging technique for discrete entropy-stable dissipation operators for ideal MHD

Author

Gregor J. Gassner, Andrew R. Winters, Stefanie Walch, and Dominik Derigs

Subjects

Physics and Astronomy (miscellaneous), Discretization, Beräkningsmatematik, Configuration entropy, FOS: Physical sciences, kinetic energy preserving, 010103 numerical & computational mathematics, Maximum entropy spectral estimation, 01 natural sciences, entropy stable, Applied mathematics, 0101 mathematics, Entropy (energy dispersal), Boltzmann's entropy formula, Mathematics, Numerical Analysis, Applied Mathematics, entropy Jacobian, Fluid Dynamics (physics.flu-dyn), Maximum entropy thermodynamics, Physics - Fluid Dynamics, Computational Physics (physics.comp-ph), Dissipation, Computer Science Applications, 010101 applied mathematics, Computational Mathematics, Classical mechanics, Modeling and Simulation, magnetohydrodynamics, Physics - Computational Physics, Joint quantum entropy

Abstract

Entropy stable schemes can be constructed with a specific choice of the numerical flux function. First, an entropy conserving flux is constructed. Secondly, an entropy stable dissipation term is added to this flux to guarantee dissipation of the discrete entropy. Present works in the field of entropy stable numerical schemes are concerned with thorough derivations of entropy conservative fluxes for ideal MHD. However, as we show in this work, if the dissipation operator is not constructed in a very specific way, it cannot lead to a generally stable numerical scheme. The two main findings presented in this paper are that the entropy conserving flux of Ismail & Roe can easily break down for certain initial conditions commonly found in astrophysical simulations, and that special care must be taken in the derivation of a discrete dissipation matrix for an entropy stable numerical scheme to be robust. We present a convenient novel averaging procedure to evaluate the entropy Jacobians of the ideal MHD and the compressible Euler equations that yields a discretization with favorable robustness properties., 10 pages, 2 figures, submitted to Journal of Computational Physics

5. A comparative study on polynomial dealiasing and split form discontinuous Galerkin schemes for under-resolved turbulence computations

Author

Andrew R. Winters, Gianmarco Mengaldo, Gregor J. Gassner, Spencer J. Sherwin, Stefanie Walch, R. C. Moura, and Joaquim Peiró

Subjects

Polynomial, Physics and Astronomy (miscellaneous), Beräkningsmatematik, Degrees of freedom (statistics), Polynomial dealiasing, 01 natural sciences, Stability (probability), 010305 fluids & plasmas, Discontinuous Galerkin method, Inviscid flow, 0103 physical sciences, Discontinuous Galerkin, FOS: Mathematics, Mathematics - Numerical Analysis, ddc:510, 0101 mathematics, Mathematics, Numerical Analysis, Spectral element methods, Applied Mathematics, Mathematical analysis, Finite difference, Computational mathematics, Numerical Analysis (math.NA), Inviscid Taylor-Green vortex, Computer Science Applications, Quadrature (mathematics), 010101 applied mathematics, Computational Mathematics, Modeling and Simulation, Split form schemes, Implicit large eddy simulation, ddc:004, ddc:600

Abstract

This work focuses on the accuracy and stability of high-order nodal discontinuous Galerkin (DG) methods for under-resolved turbulence computations. In particular we consider the inviscid Taylor-Green vortex (TGV) flow to analyse the implicit large eddy simulation (iLES) capabilities of DG methods at very high Reynolds numbers. The governing equations are discretised in two ways in order to suppress aliasing errors introduced into the discrete variational forms due to the under-integration of non-linear terms. The first, more straightforward way relies on consistent/over-integration, where quadrature accuracy is improved by using a larger number of integration points, consistent with the degree of the non-linearities. The second strategy, originally applied in the high-order finite difference community, relies on a split (or skew-symmetric) form of the governing equations. Different split forms are available depending on how the variables in the non-linear terms are grouped. The desired split form is then built by averaging conservative and non-conservative forms of the governing equations, although conservativity of the DG scheme is fully preserved. A preliminary analysis based on Burgers' turbulence in one spatial dimension is conducted and shows the potential of split forms in keeping the energy of higher-order polynomial modes close to the expected levels. This indicates that the favourable dealiasing properties observed from split-form approaches in more classical schemes seem to hold for DG. The remainder of the study considers a comprehensive set of (under-resolved) computations of the inviscid TGV flow and compares the accuracy and robustness of consistent/over-integration and split form discretisations based on the local Lax-Friedrichs and Roe-type Riemann solvers. Recent works showed that relevant split forms can stabilize higher-order inviscid TGV test cases otherwise unstable even with consistent integration. Here we show that stable high-order cases achievable with both strategies have comparable accuracy, further supporting the good dealiasing properties of split form DG. The higher-order cases achieved only with split form schemes also displayed all the main features expected from consistent/over-integration. Among test cases with the same number of degrees of freedom, best solution quality is obtained with Roe-type fluxes at moderately high orders (around sixth order). Solutions obtained with very high polynomial orders displayed spurious features attributed to a sharper dissipation in wavenumber space. Accuracy differences between the two dealiasing strategies considered were, however, observed for the low-order cases, which also yielded reduced solution quality compared to high-order results.

6. An entropy stable discontinuous Galerkin method for the shallow water equations on curvilinear meshes with wet/dry fronts accelerated by GPUs

Author

Niklas Wintermeyer, Gregor J. Gassner, Tim Warburton, and Andrew R. Winters

Subjects

Physics and Astronomy (miscellaneous), GPUs, Beräkningsmatematik, 010103 numerical & computational mathematics, Oceanografi, hydrologi och vattenresurser, 01 natural sciences, OCCA, Shallow water equations, Oceanography, Hydrology and Water Resources, Discontinuous Galerkin method, FOS: Mathematics, Polygon mesh, Mathematics - Numerical Analysis, 0101 mathematics, High order, ddc:510, Physics, Positivity preservation, Numerical Analysis, Curvilinear coordinates, Applied Mathematics, Mathematical analysis, Computational mathematics, Numerical Analysis (math.NA), Shock capturing, Computer Science Applications, 010101 applied mathematics, Computational Mathematics, Modeling and Simulation, Discontinuous Galerkin spectral element method, Discontinuous galerkin spectral element method, ddc:004, ddc:600

Abstract

We extend the entropy stable high order nodal discontinuous Galerkin spectral element approximation for the non-linear two dimensional shallow water equations presented by Wintermeyer et al. [N. Wintermeyer, A. R. Winters, G. J. Gassner, and D. A. Kopriva. An entropy stable nodal discontinuous Galerkin method for the two dimensional shallow water equations on unstructured curvilinear meshes with discontinuous bathymetry. Journal of Computational Physics, 340:200-242, 2017] with a shock capturing technique and a positivity preservation capability to handle dry areas. The scheme preserves the entropy inequality, is well-balanced and works on unstructured, possibly curved, quadrilateral meshes. For the shock capturing, we introduce an artificial viscosity to the equations and prove that the numerical scheme remains entropy stable. We add a positivity preserving limiter to guarantee non-negative water heights as long as the mean water height is non-negative. We prove that non-negative mean water heights are guaranteed under a certain additional time step restriction for the entropy stable numerical interface flux. We implement the method on GPU architectures using the abstract language OCCA, a unified approach to multi-threading languages. We show that the entropy stable scheme is well suited to GPUs as the necessary extra calculations do not negatively impact the runtime up to reasonably high polynomial degrees (around N = 7). We provide numerical examples that challenge the shock capturing and positivity properties of our scheme to verify our theoretical findings.