A conservative local discontinuous Galerkin method for the solution of nonlinear Schrdinger equation in two dimensions |
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摘 要: | In this study, we present a conservative local discontinuous Galerkin(LDG) method for numerically solving the two-dimensional nonlinear Schrdinger(NLS) equation. The NLS equation is rewritten as a firstorder system and then we construct the LDG formulation with appropriate numerical flux. The mass and energy conserving laws for the semi-discrete formulation can be proved based on different choices of numerical fluxes such as the central, alternative and upwind-based flux. We will propose two kinds of time discretization methods for the semi-discrete formulation. One is based on Crank-Nicolson method and can be proved to preserve the discrete mass and energy conservation. The other one is Krylov implicit integration factor(IIF) method which demands much less computational effort. Various numerical experiments are presented to demonstrate the conservation law of mass and energy, the optimal rates of convergence, and the blow-up phenomenon.
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A conservative local discontinuous Galerkin method for the solution of nonlinear Schrödinger equation in two dimensions |
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Authors: | RongPei Zhang XiJun Yu MingJun Li XiangGui Li |
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Institution: | 1.School of Mathematics and Systematic Sciences,Shenyang Normal University,Shenyang,China;2.Laboratory of Computational Physics,Institute of Applied Physics and Computational Mathematics,Beijing,China;3.School of Mathematics and Computational Science,Xiangtan University,Xiangtan,China;4.School of Applied Science,Beijing Information Science and Technology University,Beijing,China |
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Abstract: | In this study, we present a conservative local discontinuous Galerkin (LDG) method for numerically solving the two-dimensional nonlinear Schr¨odinger (NLS) equation. The NLS equation is rewritten as a firstorder system and then we construct the LDG formulation with appropriate numerical flux. The mass and energy conserving laws for the semi-discrete formulation can be proved based on different choices of numerical fluxes such as the central, alternative and upwind-based flux. We will propose two kinds of time discretization methods for the semi-discrete formulation. One is based on Crank-Nicolson method and can be proved to preserve the discrete mass and energy conservation. The other one is Krylov implicit integration factor (IIF) method which demands much less computational effort. Various numerical experiments are presented to demonstrate the conservation law of mass and energy, the optimal rates of convergence, and the blow-up phenomenon. |
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