Title :
Dynamic properties of push-pull DFB semiconductor lasers
Author :
Chen, Jianyao ; Maciejko, Roman ; Makino, Toshihiko
Author_Institution :
Dept. of Eng. Phys., Ecole Polytech. de Montreal, Que., Canada
fDate :
12/1/1996 12:00:00 AM
Abstract :
Using the spatially dependent multimode rate equations, we present a systematic study of small-signal dynamics of push-pull DFB lasers. The various spatial effects such as the longitudinal spatial hole burning, nonlinear gain compression, side-mode contribution, and push-pull modulation are all analyzed in a self-consistent manner. With the closed form expressions for the AM and FM responses, we show explicitly that the resonance frequency and the first cut-off frequency of push-pull DFB lasers are determined by the frequency spacing and the threshold gain difference between the lasing mode and its closest antisymmetric side mode, respectively. Numerical results reveal that a high modulation speed with a very low frequency chirp can be achieved with the push-pull DFB lasers
Keywords :
amplitude modulation; chirp modulation; distributed feedback lasers; dynamics; electro-optical modulation; frequency modulation; laser modes; laser theory; optical hole burning; semiconductor lasers; AM responses; FM responses; antisymmetric side mode; closed form expressions; cut-off frequency; dynamic properties; frequency spacing; high modulation speed; lasing mode; longitudinal spatial hole burning; nonlinear gain compression; push-pull DFB lasers; push-pull DFB semiconductor lasers; push-pull modulation; resonance frequency; self-consistent manner; side-mode contribution; small-signal dynamics; spatial effects; spatially dependent multimode rate equations; systematic study; threshold gain difference; Cutoff frequency; Equations; Frequency modulation; Laser modes; Laser theory; Optical modulation; Optical waveguides; Resonant frequency; Semiconductor lasers; Waveguide lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
