Title :
Vector Finite Difference Modesolver for Anisotropic Dielectric Waveguides
Author :
Fallahkhair, Arman B. ; Li, Kai S. ; Murphy, Thomas E.
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Maryland, College Park, MD
fDate :
6/1/2008 12:00:00 AM
Abstract :
We describe a new full-vector finite difference discretization, based upon the transverse magnetic field components, for calculating the electromagnetic modes of optical waveguides with transverse, nondiagonal anisotropy. Unlike earlier finite difference approaches, our method allows for the material axes to be arbitrarily oriented, as long as one of the principal axes coincides with the direction of propagation. We demonstrate the capabilities of the method by computing the circularly-polarized modes of a magnetooptical waveguide and the modes of an off-axis poled anisotropic polymer waveguide.
Keywords :
anisotropic media; finite difference methods; integrated optoelectronics; magneto-optical devices; optical waveguide theory; anisotropic dielectric waveguides; circularly-polarized modes; electromagnetic modes; full-vector finite difference discretization; magnetooptical waveguide; nondiagonal anisotropy; off-axis poled anisotropic polymer waveguide; optical waveguides; transverse magnetic field components; vector finite difference modesolver; Anisotropic magnetoresistance; Dielectrics; Electromagnetic fields; Electromagnetic scattering; Electromagnetic waveguides; Finite difference methods; Geometrical optics; Magnetic fields; Optical devices; Optical waveguides; Anisotropic media; Faraday effect; birefringence; dielectric waveguides; finite difference methods; optical propagation in anisotropic media;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2008.923643
