Title :
Effects of hole burning, carrier-induced losses and the carrier-dependent differential gain on the static characteristics of DFB lasers
Author_Institution :
Alcatel-Alsthom Recherche, Marcoussis, France
fDate :
11/1/1992 12:00:00 AM
Abstract :
A model solving the steady-state laser equations above threshold is presented. It calculates important laser parameters such as the threshold losses, emitted optical power, gain margin between the main and secondary modes and, spectral linewidth of any index-grating DFB laser structure. A more exact theoretical linewidth calculation considering nonuniform carrier densities and gain saturation is reported. Good agreement with experiments is found on phase-shifted lasers. The model is used to investigate the factors that determine the importance of spatial hole burning, and general design rules are proposed to reduce this effect. Gain compression combined with carrier-dependent losses is shown to limit the differential external efficiency and cause the emission wavelength to decrease and the spectral linewidth to rebroaden at high output power
Keywords :
carrier density; distributed feedback lasers; optical hole burning; optical losses; spectral line breadth; carrier-dependent differential gain; carrier-induced losses; differential external efficiency; distributed feedback lasers; emitted optical power; gain compression; gain margin; gain saturation; general design rules; index-grating DFB laser structure; laser parameters; main modes; model; nonuniform carrier densities; phase-shifted lasers; secondary modes; spatial hole burning; spectral linewidth; static characteristics; steady-state laser equations; theoretical linewidth calculation; threshold losses; Charge carrier density; Equations; Laser modes; Laser theory; Optical losses; Optical saturation; Power generation; Power lasers; Steady-state; Stimulated emission;
Journal_Title :
Lightwave Technology, Journal of
