Asymptotically exact a posteriori local discontinuous Galerkin error estimates for the one‐dimensional second‐order wave equation |
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| Authors: | Mahboub Baccouch |
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| Affiliation: | Department of Mathematics, University of Nebraska at Omaha, Omaha, Nebraska |
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| Abstract: | In this article, we analyze a residual‐based a posteriori error estimates of the spatial errors for the semidiscrete local discontinuous Galerkin (LDG) method applied to the one‐dimensional second‐order wave equation. These error estimates are computationally simple and are obtained by solving a local steady problem with no boundary condition on each element. We apply the optimal L2 error estimates and the superconvergence results of Part I of this work Baccouch, Numer Methods Partial Differential Equations 30 (2014), 862–901] to prove that, for smooth solutions, these a posteriori LDG error estimates for the solution and its spatial derivative, at a fixed time, converge to the true spatial errors in the L2‐norm under mesh refinement. The order of convergence is proved to be  , when p‐degree piecewise polynomials with  are used. As a consequence, we prove that the LDG method combined with the a posteriori error estimation procedure yields both accurate error estimates and  superconvergent solutions. Our computational results show higher  convergence rate. We further prove that the global effectivity indices, for both the solution and its derivative, in the L2‐norm converge to unity at  rate while numerically they exhibit  and  rates, respectively. Numerical experiments are shown to validate the theoretical results. © 2014 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 31: 1461–1491, 2015 |
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| Keywords: | local discontinuous Galerkin method second‐order wave equation superconvergence residual‐based a posteriori error estimates |
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