An implicit-explicit time discretization for elastic wave propagation problems in plates

We propose a new implicit-explicit scheme to address the challenge of modeling wave propagation within thin structures using the time-domain finite element method. Compared to standard explicit schemes, our approach renders a time marching algorithm with a time step independent of the plate thickness and its associated discretization parameters (mesh step and order of approximation). Relying on the standard three dimensional elastodynamics equations, our strategy can be applied to any type of material, either isotropic or anisotropic, with or without discontinuities in the thickness direction. Upon the assumption of an extruded mesh of the plate-like geometry, we show that the linear system to be solved at each time step is partially lumped thus efficiently treated. We provide numerical evidence of an adequate convergence behavior, similar to a reference solution obtained using the well-known leapfrog scheme. Further numerical investigations show significant speed up factors compared to the same reference scheme, proving the efficiency of our approach for the configurations of interest.

Automated summary

This study proposes a new implicit-explicit scheme for modeling wave propagation within thin structures using the time-domain finite element method. The proposed approach overcomes the limitation of standard explicit schemes by allowing a time marching algorithm with a time step independent of the plate thickness. The method is applicable to various materials and configurations.