Title :
Low-truncation-error finite difference equations for photonics simulation. II. Vertical-cavity surface-emitting lasers
Author :
Hadley, G. Ronald
Author_Institution :
Sandia Nat. Labs., Albuquerque, NM, USA
fDate :
1/1/1998 12:00:00 AM
Abstract :
For part I see, ibid., p. 134, 1998. The basic approach outlined in the previous article is applied to the difficult problem of computing the optical modes of a vertical-cavity surface-emitting laser. The formulation utilizes a finite difference equation based upon the lowest order term of an infinite series solution of the scalar Helmholtz equation in a local region. This difference equation becomes exact in the one-dimensional (1-D) limit, and is thus ideally suited for nearly 1-D devices such as vertical-cavity lasers. The performance of the resulting code is tested on both a simple cylindrical cavity with known solutions and an oxide-confined vertical-cavity laser structure, and the results compared against second-order-accurate code based upon Crank-Nicolson differencing
Keywords :
CAD; Helmholtz equations; codes; difference equations; electromagnetic wave propagation; finite difference methods; laser cavity resonators; laser modes; optical design techniques; semiconductor device models; semiconductor lasers; surface emitting lasers; CAD; Crank-Nicolson differencing; code; cylindrical cavity; exact 1D limit; finite difference equation; infinite series solution; laser modes; local region; low-truncation-error finite difference equations; lowest order term; nearly 1-D devices; optical modes; oxide-confined vertical-cavity laser structure; photonics simulation; scalar Helmholtz equation; second-order-accurate code; second-order-accurate code based upon Crank-Nicolson differencing; vertical-cavity lasers; vertical-cavity surface-emitting lasers; Computational modeling; Difference equations; Finite difference methods; Geometry; Laser modes; Mirrors; Optical computing; Photonics; Surface emitting lasers; Vertical cavity surface emitting lasers;
Journal_Title :
Lightwave Technology, Journal of
