A Local Macroscopic Conservative (LoMaC) Low Rank Tensor Method with the Discontinuous Galerkin Method for the Vlasov Dynamics

doi:10.1007/s42967-023-00277-7

Communications on Applied Mathematics and Computation ›› 2024, Vol. 6 ›› Issue (1): 550-575.doi: 10.1007/s42967-023-00277-7

• ORIGINAL PAPERS • Previous Articles Next Articles

A Local Macroscopic Conservative (LoMaC) Low Rank Tensor Method with the Discontinuous Galerkin Method for the Vlasov Dynamics

Wei Guo¹, Jannatul Ferdous Ema¹, Jing-Mei Qiu²

1. Department of Mathematics and Statistics, Texas Tech University, Lubbock, TX, 70409, USA;
2. Department of Mathematical Sciences, University of Delaware, Newark, DE, 19716, USA

Received:2022-10-12 Revised:2023-03-28 Published:2024-04-16
Contact: Jing-Mei Qiu,E-mail:jingqiu@udel.edu;Wei Guo,E-mail:weimath.guo@ttu.edu;Jannatul Ferdous Ema,E-mail:Jannatul-Ferdous.Ema@ttu.edu E-mail:jingqiu@udel.edu;weimath.guo@ttu.edu;Jannatul-Ferdous.Ema@ttu.edu
Supported by:
Research supported by the NSF (Grant Nos. the NSF-DMS-1818924 and 2111253), the Air Force Office of Scientific Research FA9550-22-1-0390 and Department of Energy DE-SC0023164. Research is supported by the NSF (Grant Nos. NSF-DMS-1830838 and NSF-DMS-2111383), the Air Force Office of Scientific Research FA9550-22-1-0390.

Abstract

Abstract: In this paper, we propose a novel Local Macroscopic Conservative (LoMaC) low rank tensor method with discontinuous Galerkin (DG) discretization for the physical and phase spaces for simulating the Vlasov-Poisson (VP) system. The LoMaC property refers to the exact local conservation of macroscopic mass, momentum, and energy at the discrete level. The recently developed LoMaC low rank tensor algorithm (arXiv: 2207.00518) simultaneously evolves the macroscopic conservation laws of mass, momentum, and energy using the kinetic flux vector splitting; then the LoMaC property is realized by projecting the low rank kinetic solution onto a subspace that shares the same macroscopic observables. This paper is a generalization of our previous work, but with DG discretization to take advantage of its compactness and flexibility in handling boundary conditions and its superior accuracy in the long term. The algorithm is developed in a similar fashion as that for a finite difference scheme, by observing that the DG method can be viewed equivalently in a nodal fashion. With the nodal DG method, assuming a tensorized computational grid, one will be able to (i) derive differentiation matrices for different nodal points based on a DG upwind discretization of transport terms, and (ii) define a weighted inner product space based on the nodal DG grid points. The algorithm can be extended to the high dimensional problems by hierarchical Tucker (HT) decomposition of solution tensors and a corresponding conservative projection algorithm. In a similar spirit, the algorithm can be extended to DG methods on nodal points of an unstructured mesh, or to other types of discretization, e.g., the spectral method in velocity direction. Extensive numerical results are performed to showcase the efficacy of the method.

Key words: Hierarchical Tucker (HT) decomposition, Conservative SVD, Energy conservation, Discontinuous Galerkin (DG) method

Wei Guo, Jannatul Ferdous Ema, Jing-Mei Qiu. A Local Macroscopic Conservative (LoMaC) Low Rank Tensor Method with the Discontinuous Galerkin Method for the Vlasov Dynamics[J]. Communications on Applied Mathematics and Computation, 2024, 6(1): 550-575.

TrendMD

References

[1] Arnold, D.N., Brezzi, F., Cockburn, B., Marini, L.D.:Unified analysis of discontinuous Galerkin methods for elliptic problems. SIAM J. Num. Anal. 39(5), 1749-1779 (2002)
[2] Cockburn, B., Luskin, M., Shu, C.-W., Süli, E.:Enhanced accuracy by post-processing for finite element methods for hyperbolic equations. Math. Comput. 72(242), 577-606 (2003)
[3] De Dios, B.A., Hajian, S.:High order and energy preserving discontinuous Galerkin methods for the Vlasov-Poisson system. arXiv:1209.4025 (2012)
[4] De Lathauwer, L., De Moor, B., Vandewalle, J.:A multilinear singular value decomposition. SIAM J. Matrix Anal. Appl. 21(4), 1253-1278 (2000)
[5] Gottlieb, S., Ketcheson, D.I., Shu, C.-W.:Strong Stability Preserving Runge-Kutta and Multistep Time Discretizations. World Scientific, NJ, United States (2011)
[6] Grasedyck, L.:Hierarchical singular value decomposition of tensors. SIAM J. Matrix Anal. Appl. 31(4), 2029-2054 (2010)
[7] Guo, W., Qiu, J.-M.:A low rank tensor representation of linear transport and nonlinear vlasov solutions and their associated flow maps. arXiv:2106.08834 (2021)
[8] Guo, W., Qiu, J.-M.:A conservative low rank tensor method for the Vlasov dynamics. arXiv:2106.08834 (2022)
[9] Guo, W., Qiu, J.-M.:A Local Macroscopic Conservative (LoMaC) low rank tensor method for the Vlasov dynamics. arXiv:2207.00518 (2022)
[10] Guo, W., Qiu, J.-M.:A low rank tensor representation of linear transport and nonlinear Vlasov solutions and their associated flow maps. J. Comput. Phys. 458, 111089 (2022)
[11] Hackbusch, W., Kühn, S.:A new scheme for the tensor representation. J. Fourier Anal. Appl. 15(5), 706-722 (2009)
[12] Mandal, J., Deshpande, S.:Kinetic flux vector splitting for Euler equations. Comput. Fluids 23(2), 447-478 (1994)
[13] Tucker, L.R.:Some mathematical notes on three-mode factor analysis. Psychometrika 31(3), 279-311 (1966)
[14] Xu, K., Martinelli, L., Jameson, A.:Gas-kinetic finite volume methods, flux-vector splitting, and artificial diffusion. J. Comput. Phys. 120(1), 48-65 (1995)

A Local Macroscopic Conservative (LoMaC) Low Rank Tensor Method with the Discontinuous Galerkin Method for the Vlasov Dynamics

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 5

Recommended Articles

Metrics

Comments

[1]	Joseph Hunter, Zheng Sun, Yulong Xing. Stability and Time-Step Constraints of Implicit-Explicit Runge-Kutta Methods for the Linearized Korteweg-de Vries Equation [J]. Communications on Applied Mathematics and Computation, 2024, 6(1): 658-687.
[2]	Bo Dong, Wei Wang. Numerical Investigations on the Resonance Errors of Multiscale Discontinuous Galerkin Methods for One-Dimensional Stationary Schrödinger Equation [J]. Communications on Applied Mathematics and Computation, 2024, 6(1): 311-324.
[3]	Mengjiao Jiao, Yan Jiang, Mengping Zhang. A Provable Positivity-Preserving Local Discontinuous Galerkin Method for the Viscous and Resistive MHD Equations [J]. Communications on Applied Mathematics and Computation, 2024, 6(1): 279-310.
[4]	Fangyao Zhu, Juntao Huang, Yang Yang. Bound-Preserving Discontinuous Galerkin Methods with Modified Patankar Time Integrations for Chemical Reacting Flows [J]. Communications on Applied Mathematics and Computation, 2024, 6(1): 190-217.
[5]	Xiaoyi Liu, Tingchun Wang, Shilong Jin, Qiaoqiao Xu. Two Energy-Preserving Compact Finite Difference Schemes for the Nonlinear Fourth-Order Wave Equation [J]. Communications on Applied Mathematics and Computation, 2022, 4(4): 1509-1530.