Title :
Relaxation oscillation frequency of DFB lasers with gain coupling
Author :
Chen, Jianyao ; Maciejko, Roman ; Champagne, Alain ; Makino, Toshihiko
Author_Institution :
Lab. of Optoelectron., Ecole Polytech., Montreal, Que., Canada
fDate :
11/1/1995 12:00:00 AM
Abstract :
Using the spatially-dependent rate equations based on the Green´s function analysis, we investigate the dependency of the relaxation oscillation frequency on the complex coupling coefficient and other parameters of gain-coupled DFB lasers by simultaneously considering spatial-hole-burning, gain saturation and gain compression. An explicit expression for the relaxation oscillation frequency for DFB lasers including the longitudinal spatial effects has been obtained. It is found that antiphase gain-coupling significantly enhances the local effective differential gain in the gain-coupled DFB laser and hence increases the relaxation oscillation frequency. We have also shown for the first time that the modal linewidth enhancement factor αM plays an important role in determining the relaxation oscillation frequency of gain-coupled DFB lasers, especially when the built-in index coupling is weak
Keywords :
Green´s function methods; distributed feedback lasers; laser modes; laser theory; optical couplers; optical hole burning; optical modulation; refractive index; semiconductor lasers; spectral line breadth; DFB lasers; Green´s function analysis; antiphase gain-coupling; built-in index coupling; complex coupling coefficient; gain compression; gain coupling; gain saturation; gain-coupled DFB laser; gain-coupled DFB lasers; longitudinal spatial effects; modal linewidth enhancement factor; relaxation oscillation frequency; spatial-hole-burning; spatially-dependent rate equations; Distributed Bragg reflectors; Distributed feedback devices; Equations; Fiber lasers; Frequency; Laser feedback; Laser modes; Optical coupling; Optical fiber communication; Semiconductor lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
