Title :
Three-dimensional finite difference beam propagation algorithms for photonic devices
Author :
Lee, P.C. ; Schulz, D. ; Voges, E.
Author_Institution :
Lehrstuhl fuer Hochfrequenztech., Dortmund Univ., Germany
fDate :
12/1/1992 12:00:00 AM
Abstract :
Finite difference beam propagation techniques are developed for photonic devices with step-index distributions and arbitrarily large index differences. One technique, the eigenvector expansion method allows large propagation steps along uniform waveguide sections. The second technique, a propagation matrix series expansion method, is particularly suitable for three-dimensional wave propagation simulations. It can easily handle 105 discretization points on personal computers or workstations. The first method employs absorbing boundary conditions while the second utilizes transparent boundary conditions at the edges of the computational windows. The accuracy and applicability of these techniques is demonstrated for several 2-D and 3-D test structures
Keywords :
boundary-value problems; eigenvalues and eigenfunctions; finite difference methods; optical waveguide theory; refractive index; 3D finite difference beam propagation; 3D wave propagation simulations; absorbing boundary conditions; arbitrarily large index differences; beam propagation algorithms; computational windows; discretization points; eigenvector expansion method; personal computers; photonic devices; propagation matrix series expansion method; propagation steps; step-index distributions; test structures; transparent boundary conditions; uniform waveguide sections; workstations; Circuit testing; Eigenvalues and eigenfunctions; Electromagnetic propagation; Electromagnetic waveguides; Equations; Finite difference methods; Optical devices; Optical propagation; Optical waveguides; Transmission line matrix methods;
Journal_Title :
Lightwave Technology, Journal of
