Title :
An efficient FDTD implementation of the PML with CFS in general media
Author :
Roden, J.A. ; Gedney, S.
Author_Institution :
Personal Syst. Group, IBM Corp., Research Triangle Park, NC, USA
Abstract :
Perfectly matched layer (PML) absorbing media has proven to be the most robust and efficient technique for the termination of FDTD lattices. Unfortunately, the PML can still suffer from late time reflections when terminating highly elongated lattices or when simulating fields with very long time signatures. This is partly due to the weakly causal nature of the PML. Alternatively, a strictly causal PML was introduced in Kuzuoglu and Mittra (1996). The resulting tensor is referred to here as the complex frequency shifted (CFS) tensor. The application of this technique within the FDTD has been presented previously. Here, the formulation is postulated for a generalized medium, including lossy, dispersive, anisotropic, or non-linear media. For such a medium, there are no additional memory requirements as compared to the standard FDTD/PML methods. Furthermore, it is demonstrated that it accurately absorbs highly oblique incident waves with long time signatures and is computationally efficient.
Keywords :
absorbing media; anisotropic media; dispersive media; electromagnetic wave absorption; finite difference time-domain analysis; inhomogeneous media; CFS; FDTD implementation; FDTD lattices; PML; anisotropic media; complex frequency shifted tensor; dispersive media; general media; generalized medium; highly oblique incident waves; lossy media; memory requirements; nonlinear media; perfectly matched layer absorbing media; Convolution; Electromagnetic scattering; Finite difference methods; Frequency; Laplace equations; Lattices; Perfectly matched layers; Robustness; Tensile stress; Time domain analysis;
Conference_Titel :
Antennas and Propagation Society International Symposium, 2000. IEEE
Conference_Location :
Salt Lake City, UT, USA
Print_ISBN :
0-7803-6369-8
DOI :
10.1109/APS.2000.874457
