Title :
Full vectorial finite-element-based imaginary distance beam propagation solution of complex modes in optical waveguides
Author :
Obayya, S.S.A. ; Rahman, B. M Azizur ; Grattan, Kenneth T V ; El-Mikati, H.A.
Author_Institution :
Sch. of Eng., City Univ., London, UK
fDate :
6/1/2002 12:00:00 AM
Abstract :
In this paper, we address accurate computation of complex propagation constants and field distributions of different modes, in general, lossless and lossy optical dielectric waveguides. Using the vector finite-element formulation of the beam propagation method combined with the imaginary distance propagation technique, sequence of both the guided and leaky modes can be accurately calculated. To show the versatility and numerical precision of the proposed technique, we compute the modes of three different three-dimensional (3-D) waveguide structures and compare the results against those of other, different, vector formulations. Further, we present the design of a higher order mode filtering device, based on a 3-D leaky mode optical waveguide
Keywords :
finite element analysis; optical design techniques; optical losses; optical waveguide filters; optical waveguide theory; vectors; 3D waveguide structures; beam propagation method; complex modes; complex propagation constants; field distributions; full vectorial finite-element-based imaginary distance beam propagation solution; guided modes; higher order mode filtering; imaginary distance propagation; leaky mode optical waveguide; leaky modes; lossless optical dielectric waveguides; lossy optical dielectric waveguides; optical waveguide filters; optical waveguides; vector finite-element formulation; vector formulations; Dielectric losses; Distributed computing; Finite element methods; Optical computing; Optical filters; Optical losses; Optical propagation; Optical waveguides; Propagation constant; Propagation losses;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2002.1018817
