Stability analysis of Arbitrary-Lagrangian-Eulerian ADER-DG methods on classical and degenerate spacetime geometries
Abstract
In this paper, we present a thorough von Neumann stability analysis of explicit and implicit Arbitrary-Lagrangian-Eulerian (ALE) ADER discontinuous Galerkin (DG) methods on classical and degenerate spacetime geometries for hyperbolic equations.
First, we rigorously study CFL stability conditions for the explicit ADER-DG method, confirming results widely used in the literature while specifying their limitations.
Moreover, we discuss stability bounds for ALE methods and characterize the admissible range of grid velocities once a target CFL is fixed.
Next, we extend the stability study to ADER-DG in the presence of degenerate spacetime elements, with zero size at the beginning and the end of the time step, but with a non zero spacetime volume.
This kind of elements has been introduced in a series of articles on direct ALE methods by Gaburro et al. to connect via spacetime control volumes regenerated Voronoi tessellations after a topology change.
Here, we imitate this behavior in a 1d surrogate setting by fictitiously inserting degenerate elements in between two cells.
We show that over this simplified degenerate spacetime geometry, both for the explicit and implicit ADER-DG, the von Neumann analysis leads to the same CFL stability conditions as those for classical geometries, laying the theoretical foundations for their use in the context of ALE methods.
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