Discontinuous Galerkin Method For The One Dimensional Simulation Of Shallow Water Flows.
Abstract
A numerical solution for the one-dimensional (1D) hyperbolic conservation
law is presented, based on the Runge Kutta Discontinuous Galerkin Method (RKDG).
The RKDG scheme combines some properties of the finite element and finite-volume tech-
niques, resulting on a very attractive method because of its formal high-order accuracy, its
ability to handle complicated geometries, its adaptability to parallelization, and its abil-
ity to capture discontinuities without producing spurious oscillations. In this paper, we
consider some scalar conservation equations to ilustrate the method's properties in one
spatial dimension (1-D). Finally, the 1-D shallow water equations are discretized with the
RKDG. A comparison with an exact solution is made to illustrate the capability of the
method to handle strong discontinuities with relative small number of elements.
law is presented, based on the Runge Kutta Discontinuous Galerkin Method (RKDG).
The RKDG scheme combines some properties of the finite element and finite-volume tech-
niques, resulting on a very attractive method because of its formal high-order accuracy, its
ability to handle complicated geometries, its adaptability to parallelization, and its abil-
ity to capture discontinuities without producing spurious oscillations. In this paper, we
consider some scalar conservation equations to ilustrate the method's properties in one
spatial dimension (1-D). Finally, the 1-D shallow water equations are discretized with the
RKDG. A comparison with an exact solution is made to illustrate the capability of the
method to handle strong discontinuities with relative small number of elements.
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