Title :
A transfer matrix method based large-signal dynamic model for multielectrode DFB lasers
Author :
Davis, M.G. ; O´Dowd, R.F.
Author_Institution :
Dept. of Electron. Eng., Univ. Coll. Dublin, Ireland
fDate :
11/1/1994 12:00:00 AM
Abstract :
A large-signal dynamic model capable of modeling the transient behavior of the output power and wavelength of multielectrode DFB lasers is described here. The key feature of the model is the use of a modified form of the transfer matrix method resulting in a time-dependent implementation of this technique. Other features are the inclusion of longitudinal spatial hole burning and nonlinear gain in the model. The versatility of the model is demonstrated in an analysis of the response of a two-electrode DFB laser under large-signal direct current modulation which illustrates the important role played by longitudinal spatial hole burning. The limited use of wavelength tunability in controlling chirp is also demonstrated. However, a scheme to improve the damping mechanism through nonuniform excitation called backbiasing is proposed. Finally, wavelength switching is demonstrated using the model
Keywords :
distributed feedback lasers; electrodes; laser theory; optical hole burning; optical modulation; semiconductor device models; semiconductor lasers; transfer function matrices; backbiasing; controlling chirp; damping mechanism; large-signal direct current modulation; large-signal dynamic model; longitudinal spatial hole burning; multielectrode DFB lasers; nonlinear gain; nonuniform excitation; output power; time-dependent implementation; transfer matrix method; transient behavior; two-electrode DFB laser; wavelength switching; wavelength tunability; Charge carrier density; Chirp modulation; Frequency modulation; Laser modes; Power generation; Power lasers; Power system transients; Pump lasers; Refractive index; Transmission line matrix methods;
Journal_Title :
Quantum Electronics, IEEE Journal of
