An h-Adaptive RKDG Method for Two-Dimensional Detonation Wave Simulations

Gao, Hongqiang Zhu and Zhen

doi:10.4208/eajam.100318.010718

EAJAM

2019

DOI: 10.4208/eajam.100318.010718

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An h-Adaptive RKDG Method for Two-Dimensional Detonation Wave Simulations

Hongqiang Zhu and Zhen Gao¹

Abstract: An h-adaptive Runge-Kutta discontinuous Galerkin (RKDG) method with a positivity-preserving technique to simulate classical two-dimensional detonation waves is developed. The KXRCF troubled-cell indicator is used to detect the troubled cells with possible discontinuities or high gradients. At each time-level, an adaptive mesh is generated by refining troubled cells and coarsening others. In order to avoid the situations where detonation front moves too fast and there are not enough cells to describe detonation… Show more

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Solution property preserving reconstruction BVD+MOOD scheme for compressible euler equations with source terms and detonations

et al. 2020

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In "Solution Property Reconstruction for Finite Volume scheme: a BVD+MOOD framework", Int. J. Numer. Methods Fluids, 2020, we have designed a novel solution property preserving reconstruction, so-called multi-stage BVD-MOOD scheme. The scheme is able to maintain a high accuracy in smooth profile, eliminate the oscillations in the vicinity of discontinuity, capture sharply discontinuity and preserve some physical properties like the positivity of density and pressure for the Euler equations of compressible gas dynamics. In this paper, we present an extension of this approach for the compressible Euler equations supplemented with source terms (e.g., gravity, chemical reaction). One of the main challenges when simulating these models is the occurrence of negative density or pressure during the time evolution, which leads to a blow-up of the computation. General compressible Euler equations with different type of source terms are considered as models for physical situations such as detonation waves. Then, we illustrate the performance of the proposed scheme via a numerical test suite including genuinely demanding numerical tests. We observe that the present scheme is able to preserve the physical properties of the numerical solution still ensuring robustness and accuracy when and where appropriate.

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Solution property preserving reconstruction BVD+MOOD scheme for compressible euler equations with source terms and detonations

et al. 2020

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An h-adaptive local discontinuous Galerkin method for second order wave equation: Applications for the underwater explosion shock hydrodynamics

Liu

Zhang

et al. 2022

Ocean Engineering

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An h-Adaptive RKDG Method for Two-Dimensional Detonation Wave Simulations

Cited by 2 publications

References 39 publications

Solution property preserving reconstruction BVD+MOOD scheme for compressible euler equations with source terms and detonations

Solution property preserving reconstruction BVD+MOOD scheme for compressible euler equations with source terms and detonations

An h-adaptive local discontinuous Galerkin method for second order wave equation: Applications for the underwater explosion shock hydrodynamics

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