Title :
Low-truncation-error finite difference equations for photonics simulation. I. Beam propagation
Author :
Hadley, G. Ronald
Author_Institution :
Sandia Nat. Labs., Albuquerque, NM, USA
fDate :
1/1/1998 12:00:00 AM
Abstract :
A methodology is presented that allows the derivation of low-truncation-error finite difference equations for photonics simulation. This methodology is applied to the case of wide-angle beam propagation in two dimensions, resulting in finite difference equations for both TE and TM polarization that are quasi-fourth-order accurate even in the presence of interfaces between dissimilar dielectrics. This accuracy is accomplished without an appreciable increase in numerical overhead and is concretely demonstrated for two test problems having known solutions. These finite difference equations facilitate an approach to the ideal of grid-independent computing and should allow the simulation of relevant photonics devices on personal computers
Keywords :
CAD; difference equations; electromagnetic wave polarisation; electromagnetic wave propagation; errors; finite difference methods; optical design techniques; optical elements; semiconductor device models; semiconductor lasers; 2D wide-angle beam propagation; CAD; M polarization; TE polarization; beam propagation; dissimilar dielectrics; grid-independent computing; interfaces; known solutions; low-truncation-error finite difference equations; numerical overhead; personal computers; photonics device simulation; photonics simulation; quasi-fourth-order accurate; test problems; Computational modeling; Dielectrics; Difference equations; Finite difference methods; Grid computing; Optical computing; Photonics; Polarization; Tellurium; Testing;
Journal_Title :
Lightwave Technology, Journal of
