Discontinuous Galerkin Methods for the Vlasov--Maxwell Equations

Cheng, Yingda; Gamba, Irene M.; Li, Fengyan; Morrison, Philip

doi:10.1137/130915091

Cited by 55 publications

(100 citation statements)

References 64 publications

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“…The discontinuous Galerkin method is selected for its robustness to work well for kinetic equations in phase space, Maxwell's electromagnetic equations, and fluid equations in physical space with multiple contemporary examples for these application areas [12,13,14,15,16,17,18]. Additionally, the explicit method is straightforward to implement and well suited for emerging high performance computing architectures as described in Chapters 4 and 9.…”

Section: Methodsmentioning

confidence: 99%

“…(3.12) is developed here as a compact linear algebra system per-node and per-element to evaluate the time derivative . 13) where the geometric Jacobian J k = ∂r ∂x…”

Section: Nodal Discontinuous Galerkin Semi-discrete Implementationmentioning

confidence: 99%

“…[13] was reproduced as one means to validate the WARPM Vlasov-Maxwell model implementation in (1D + 2V ).…”

Section: Streaming Weibel Instabilitymentioning

confidence: 99%

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A Kinetic Vlasov Model for Plasma Simulation Using Discontinuous Galerkin Method on Many-Core Architectures

Reddell¹

2016

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A continuum kinetic model for plasma based on the Vlasov-Maxwell system for multiple particle species is developed. Consideration is added for boundary conditions in a truncated velocity domain and supporting wall interactions. A scheme to scale the velocity domain for multiple particle species with different temperatures and particle mass while sharing one computational mesh is described. A method for assessing the degree to which the kinetic solution differs from a Maxwell-Boltzmann distribution is introduced and tested on a thoroughly studied test case.The discontinuous Galerkin numerical method is extended for efficient solution of hyperbolic conservation laws in five or more particle phase-space dimensions using tensor-product hypercube elements with arbitrary polynomial order. A scheme for velocity moment integration is integrated as required for coupling between the plasma species and electromagnetic waves.A new high performance simulation code WARPM is developed to efficiently implement the model and numerical method on emerging many-core supercomputing architectures.WARPM uses the OpenCL programming model for computational kernels and task parallelism to overlap computation with communication. WARPM single-node performance and parallel scaling efficiency are analyzed with bottlenecks identified guiding future directions for the implementation.The plasma modeling capability is validated against physical problems with analytic solutions and well established benchmark problems.

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Section: Methodsmentioning

confidence: 99%

“…(3.12) is developed here as a compact linear algebra system per-node and per-element to evaluate the time derivative . 13) where the geometric Jacobian J k = ∂r ∂x…”

Section: Nodal Discontinuous Galerkin Semi-discrete Implementationmentioning

confidence: 99%

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A Kinetic Vlasov Model for Plasma Simulation Using Discontinuous Galerkin Method on Many-Core Architectures

Reddell¹

2016

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“…For SD studies relevant to our approach see, e.g., [1,2] and the references therein some containing also further studies involving discontinuous Galerkin schemes and their developments. A priori error estimates for a discontinuous Galerkin approach, that is not based on SD framework, are derived in [8]. The study of [8] relies on an appropriate choice of numerical flux and, unlike our fully discrete scheme, is split into separate spatial and temporal discretizations.…”

mentioning

confidence: 99%

“…A priori error estimates for a discontinuous Galerkin approach, that is not based on SD framework, are derived in [8]. The study of [8] relies on an appropriate choice of numerical flux and, unlike our fully discrete scheme, is split into separate spatial and temporal discretizations.…”

mentioning

confidence: 99%

A posteriori error estimates for the one and one-half Dimensional Relativistic Vlasov–Maxwell system

Asadzadeh

Standar

2017

Bit Numer Math

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This paper concerns a posteriori error analysis for the streamline diffusion (SD) finite element method for the one and one-half dimensional relativistic VlasovMaxwell system. The SD scheme yields a weak formulation, that corresponds to an add of extra diffusion to, e.g. the system of equations having hyperbolic nature, or convection-dominated convection diffusion problems. The a posteriori error estimates rely on dual formulations and yield error controls based on the computable residuals. The convergence estimates are derived in negative norms, where the error is split into an iteration and an approximation error and the iteration procedure is assumed to converge.

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A positive preserving gas‐kinetic scheme for relativistic Vlasov‐Bhatnagar‐Gross‐Krook‐Maxwell model

Wang

Zhang

2022

Numerical Methods in Fluids

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A positive preserving scheme is proposed for Vlasov-Bhatnagar-Gross-Krook (BGK)-Maxwell model to simulate the laser-plasma-interaction with relativistic effect. The Strang-splitting method is adopted and the Vlasov-BGK equation is divided into two parts, the kinetic part and acceleration part. Asymptotic gas-kinetic scheme is designed for the kinetic part and the solver for p direction is analytically accurate along the characteristic. Maxwell equations are solved by characteristic line method. The scheme is proved positive preserving. Stimulated Raman Scattering and Relativistic Modulational Instability are used to verify the validity of scheme.

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Discontinuous Galerkin Methods for the Vlasov--Maxwell Equations

Cited by 55 publications

References 64 publications

A Kinetic Vlasov Model for Plasma Simulation Using Discontinuous Galerkin Method on Many-Core Architectures

A Kinetic Vlasov Model for Plasma Simulation Using Discontinuous Galerkin Method on Many-Core Architectures

A posteriori error estimates for the one and one-half Dimensional Relativistic Vlasov–Maxwell system

A positive preserving gas‐kinetic scheme for relativistic Vlasov‐Bhatnagar‐Gross‐Krook‐Maxwell model

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