Title :
A physics-based three-dimensional model for distributed feedback laser diodes
Author :
Li, Xun ; Sadovnikov, A.D. ; Huang, W.-P. ; Makino, Toshihiko
Author_Institution :
Dept. of Electr. & Comput. Eng., Waterloo Univ., Ont., Canada
fDate :
9/1/1998 12:00:00 AM
Abstract :
A comprehensive physics-based three-dimensional (3-D) model for distributed feedback (DFB) lasers is developed and presented. The model considers self-consistently optical confinement, carrier transport and heat transfer over the two-dimensional (2-D) cross section. It also accounts for the longitudinal spatial hole-burning effect along the laser cavity. A rigorous optical gain model is incorporated into the 3-D model. A number of novel techniques are used in implementation of the model for efficient simulation of de and ac performance. The simulator runs efficiently on a personal computer and can be incorporated as part of the computer-aided engineering tools for the design and analysis of DFB lasers
Keywords :
CAD; carrier mobility; distributed feedback lasers; laser cavity resonators; laser theory; optical hole burning; physics computing; semiconductor device models; semiconductor lasers; 2D cross section; DFB laser design analysis; DFB laser model; carrier transport; computer-aided engineering tools; distributed feedback laser diodes; heat transfer; laser cavity; longitudinal spatial hole-burning effect; personal computer; physics-based 3D model; physics-based three-dimensional model; rigorous optical gain model; self-consistently optical confinement; Analytical models; Carrier confinement; Computational modeling; Distributed feedback devices; Heat transfer; Laser feedback; Laser modes; Laser theory; Optical feedback; Two dimensional displays;
Journal_Title :
Quantum Electronics, IEEE Journal of
