Title :
Fourier Decomposition Analysis of Anisotropic Inhomogeneous Dielectric Waveguide Structures
Author_Institution :
Univ. of Pennsylvania, Philadelphia
Abstract :
In this paper, we extend the Fourier decomposition method to compute both propagation constants and the corresponding electromagnetic field distributions of guided waves in millimeter-wave and integrated optical structures. Our approach is based on field Fourier expansions of a pair of wave equations, which have been derived to handle inhomogeneous mediums with diagonalized permittivity and permeability tensors. The tensors are represented either by a grid of homogeneous rectangles or by distribution functions defined over rectangular domains. Using the Fourier expansion, partial differential equations are converted to a matrix eigenvalue problem that correctly models this class of dielectric structures. Finally, numerical results are presented for various channel waveguides and are compared with those of other literature to validate the formulation.
Keywords :
anisotropic media; dielectric waveguides; eigenvalues and eigenfunctions; inhomogeneous media; integrated optics; optical waveguide theory; partial differential equations; Fourier decomposition analysis; anisotropic dielectric waveguide; diagonalized permittivity; electromagnetic field distributions; field Fourier expansions; inhomogeneous dielectric waveguide; integrated optical structures; matrix eigenvalue problem; millimeter-wave structure; partial differential equations; permeability tensors; propagation constants; wave equations; Anisotropic magnetoresistance; Dielectrics; Distributed computing; Electromagnetic fields; Electromagnetic waveguides; Optical computing; Optical waveguides; Partial differential equations; Propagation constant; Tensile stress; Anisotropic; Fourier decomposition method; dielectric waveguide; inhomogenous;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2007.902616
