A preconditioned 3-D multi-region fast multipole solver for seismic wave propagation in complex geometries.
2012
Publication type:
Paper in peer-reviewed journals
Journal:
Commun. Comput. Phys., vol. 11(2), pp. 594-609
External link:
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Abstract:
The analysis of seismic wave propagation and amplification in complex geological structures requires efficient numerical methods. In this article, following up on recent studies devoted to the formulation, implementation and evaluation of 3-D single- and multi-region elastodynamic fast multipole boundary element methods (FM-BEMs), a simple preconditioning strategy is proposed. Its efficiency is demonstrated on both the single- and multi-region versions using benchmark examples (scattering of plane waves by canyons and basins). Finally, the preconditioned FM-BEM is applied to the scattering of plane seismic waves in an actual configuration (alpine basin of Grenoble, France), for which the high velocity contrast is seen to significantly affect the overall efficiency of the multi-region FM-BEM.
BibTeX:
@article{Cha-Sem-Bon-2012, author={Stéphanie Chaillat and Jean-François Semblat and Marc Bonnet }, title={A preconditioned 3-D multi-region fast multipole solver for seismic wave propagation in complex geometries. }, doi={10.4208/cicp.231209.030111s }, journal={Commun. Comput. Phys. }, year={2012 }, volume={11(2) }, pages={594--609}, }