Title :
Detailed transfer matrix method-based dynamic model for multisection widely tunable GCSR lasers
Author :
Lavrova, Olga A. ; Blumenthal, Daniel J.
Author_Institution :
Dept. of Electr. & Comput. Eng., California Univ., Santa Barbara, CA, USA
Abstract :
A theoretical model suitable for both static and dynamic analysis of widely tunable multisection grating assisted codirectional coupler with rear sampled grating reflector (GCSR) lasers is described in this paper. For the first time wide static tunability as well as transient behavior of such lasers are simulated. The theoretical model is based on the transfer matrix method (TMM) in combination with multimode rate equation analysis and takes into account a number of physical processes in the laser cavity such as longitudinal mode spatial hole burning, nonlinear gain compression, and refractive index changes with carrier injection. Static and dynamic characteristics simulated using the proposed approach agree with the experimental results presented in the paper.
Keywords :
diffraction gratings; distributed Bragg reflector lasers; laser theory; laser tuning; matrix algebra; optical directional couplers; optical hole burning; semiconductor device models; semiconductor lasers; carrier injection; detailed transfer matrix method-based dynamic model; dynamic characteristics; laser cavity; longitudinal mode spatial hole burning; multimode rate equation analysis; multisection widely tunable GCSR lasers; nonlinear gain compression; physical processes; rear sampled grating reflector laser; refractive index changes; theoretical model; transfer matrix method; transient behavior; wide static tunability; widely tunable multisection grating assisted codirectional coupler; Distributed Bragg reflectors; Gratings; Laser modes; Laser theory; Laser transitions; Laser tuning; Nonlinear equations; Optical coupling; Tunable circuits and devices; Wavelength division multiplexing;
Journal_Title :
Lightwave Technology, Journal of
