Domain decomposition and upscaling technique for metascreens

• Michael Leumüller ^[1] ; Karl Hollaus ^[1] ; Joachim Schöberl ^[1]
  1. [1] Vienna University of Technology

     Vienna University of Technology

     Innere Stadt, Austria

     
• Localización: Compel: International journal for computation and mathematics in electrical and electronic engineering, ISSN 0332-1649, Vol. 41, Nº 3, 2022, págs. 938-953
• Idioma: inglés
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• Resumen

  • Purpose – This paper aims to consider a multiscale electromagnetic wave problem for a housing with a ventilation grill. Using the standard finite element method to discretise the apertures leads to an unduly large number of unknowns. An efficient approach to simulate the multiple scales is introduced. The aim is to significantly reduce the computational costs.

    Design/methodology/approach – A domain decomposition technique with upscaling is applied to cope with the different scales. The idea is to split the domain of computation into an exterior domain and multiple non-overlapping sub-domains. Each sub-domain represents a single aperture and uses the same finite element mesh. The identical mesh of the sub-domains is efficiently exploited by the hybrid discontinuous Galerkin method and a Schur complement which facilitates the transition from fine meshes in the sub-domains to a coarse mesh in the exterior domain. A coarse skeleton grid is used on the interface between the exterior domain and the individual sub-domains to avoid large dense blocks in the finite element discretisation matrix.

    Findings – Applying a Schur complement to the identical discretisation of the sub-domains leads to a method that scales very well with respect to the number of apertures.

    Originality/value – The error compared to the standard finite element method is negligible and the computational costs are significantly reduced.