Application of multigrid method to lightwave propagation in two-dimensional optical waveguide

A study of the path-integral method to compute the eigen¨alues in two-dimensional wa¨eguides is presented. The frequencydomain fields are computed by the path-integral method in the longitudinal and trans¨erse directions in wa¨eguides containing a delta-function source. The frequency-domain field is

by using the BHW, better approximate the original w Ž . Ž .x signals E , H than those treated by using the i i RGW, and this, in turn, helps reduce the iteration time in the time domain by as much as a factor of 10.

This paper describes two strategies for the accurate computations of polential derivalives in boundary element methods. The first method regularizes the quasi singularity in a fundamental solution by referring the potential and its derivatives at the boundary point nearest to a calculation point in

The fourth-order ®nite difference method is combined with the vorticity±streamfunction formulation in generalized co-ordinates. Direct numerical simulations are performed for channel ¯ows with and without surface roughness at a Reynolds number of 10 4 . The present results are in good agreement with