A spatial high-order hexahedral discontinuous Galerkin method to solve Maxwell's equations in time domain

Gary Cohen, Xavier Ferrieres and Sébastien Pernet
2006
Publication type:
Paper in peer-reviewed journals
Journal:
Journal of Computational Physics, vol. 217(2), pp. 340-363
Abstract:
In this paper, we present a non-dissipative spatial high-order discontinuous Galerkin method to solve the Maxwell equations in the time domain. The non-intuitive choice of the space of approximation and the basis functions induce an important gain for mass, stiffness and jump matrices in terms of memory. This spatial approximation, combined with a leapfrog scheme in time, leads also to a fast explicit and accurate method. A study of the dispersive error is carried out and a stability condition for the proposed scheme is established. Some comparisons with other schemes are presented to validate the new scheme and to point out its advantages. Finally, in order to improve the efficiency of the method in terms of CPU time on general unstructured meshes, a strategy of local time-stepping is proposed.
BibTeX:
@article{Coh-Fer-Per-2006-1,
    author={Gary Cohen and Xavier Ferrieres and Sébastien Pernet },
    title={A spatial high-order hexahedral discontinuous Galerkin method 
           to solve Maxwell's equations in time domain },
    doi={10.1016/j.jcp.2006.01.004 },
    journal={Journal of Computational Physics },
    year={2006 },
    volume={217(2) },
    pages={340--363},
}