Applies sparse-grid combination technique to space-time discretization of the wave equation, providing convergence rates and complexity estimates.
A priori and a posteriori error estimates of a $\mathcal C^0$-in-time method for the wave equation in second order formulation
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abstract
We establish fully-discrete a priori and semi-discrete in time a posteriori error estimates for a discontinuous-continuous Galerkin discretization of the wave equation in second order formulation; the resulting method is a Petrov-Galerkin scheme based on piecewise polynomial test functions and continuous piecewise polynomial trial functions in time, respectively. Crucial tools in the a priori analysis for the fully-discrete formulation are the design of suitable projection and interpolation operators extending those used in the parabolic setting, and stability estimates based on a nonstandard choice of the test function; a priori estimates are shown, which are measured in $L^\infty$-type norms in time. For the semi-discrete in time formulation, we exhibit reliable a posteriori error estimates for the error measured in the $L^\infty(L^2)$ norm with fully explicit constants; to this aim, we design a reconstruction operator into $\mathcal C^1$ piecewise polynomials over the time grid with optimal approximation properties in terms of the polynomial degree distribution and the time steps. Numerical examples illustrate the theoretical findings.
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math.NA 2verdicts
UNVERDICTED 2representative citing papers
The authors derive rigorous a posteriori error bounds in the L^∞(L²) norm for an arbitrary-order space-time FEM for the wave equation that supports adaptive mesh modification via temporal reconstructions.
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A space-time sparse-grid method for the wave equation
Applies sparse-grid combination technique to space-time discretization of the wave equation, providing convergence rates and complexity estimates.