Extension of the contour integral method for the modeling of TE scattering in two-dimensional photonic structures using the duality principle

Preibisch, JanJanPreibischSchuster, ChristianChristianSchuster2020-03-092020-03-092016-11-1610th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics, METAMATERIALS 2016: 7746520, 292-294 (2016-11-16)http://hdl.handle.net/11420/5246The Contour Integral Method (CIM) is a numerically efficient modeling technique for planar or infinitely extended two-dimensional (2-D) structures. In the optical regime, the CIM has already been adapted and applied for the modeling of TM0z-mode scattering in photonic crystals. In this work the dual case of TE0z-mode scattering is addressed. Making use of the duality principle, expressions for the behavior of the TE0z-mode can be derived from the system matrices associated with the TE0z-mode. This allows to reuse use formulas and program code written for the TE0z-mode with minimal adjustments. The results are validated by comparison to full-wave simulations.enTechnikExtension of the contour integral method for the modeling of TE scattering in two-dimensional photonic structures using the duality principleConference Paper10.1109/MetaMaterials.2016.7746520Other