In this work, we present a high-order Discontinuous Galerkin time integration scheme for second-order (in time) differential systems that typically arise from the space discretization of the elastodynamics equation. By rewriting the original equation as a system of first-order differential equations we introduce the method and show that the resulting discrete formulation is well-posed, stable, and retains a super-optimal rate of convergence with respect to the discretization parameters, namely the time step and the polynomial approximation degree. A set of two-and three-dimensional numerical experiments confirm the theoretical bounds. Finally, the method is applied to real geophysical simulations.
A discontinuous Galerkin time integration scheme for second order differential equations with applications to seismic wave propagation problems
Antonietti P. F.;Mazzieri I.;Migliorini F.
2023-01-01
Abstract
In this work, we present a high-order Discontinuous Galerkin time integration scheme for second-order (in time) differential systems that typically arise from the space discretization of the elastodynamics equation. By rewriting the original equation as a system of first-order differential equations we introduce the method and show that the resulting discrete formulation is well-posed, stable, and retains a super-optimal rate of convergence with respect to the discretization parameters, namely the time step and the polynomial approximation degree. A set of two-and three-dimensional numerical experiments confirm the theoretical bounds. Finally, the method is applied to real geophysical simulations.| File | Dimensione | Formato | |
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2023-AntoniettiMazzieriMigliorini.pdf
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