Title :
Modeling noise and modulation performance of fiber grating external cavity lasers
Author :
Premaratne, Malin ; Lowery, Arthur J. ; Ahmed, Zaheer ; Novak, Dalma
Author_Institution :
Dept. of Electr. & Electron. Eng., Melbourne Univ., Parkville, Vic., Australia
fDate :
4/1/1997 12:00:00 AM
Abstract :
A detailed model is developed for analyzing fiber grating external cavity lasers for both static and small-signal modulation conditions. The chip and package parasitics and leakage current induced distortion are included. The composite system is solved analytically in the small-signal regime using a Volterra functional series expansion method. As an application of the model, a thorough analysis of the appearance of nulls close to the harmonics of the cavity resonance frequency in the noise and modulation spectra is given. We show that the appearance of these nulls can be explained using the interplay of amplitude and phase coupling between laser diode and external resonant cavity. A signal flow graph approach is introduced which identifies methods of minimizing the nulls
Keywords :
diffraction gratings; laser beams; laser cavity resonators; laser feedback; laser noise; laser theory; leakage currents; optical fibres; optical modulation; quantum noise; semiconductor device models; semiconductor device packaging; semiconductor lasers; Volterra functional series expansion method; amplitude; cavity resonance frequency; chip parasitics; composite system; fiber Bragg grating; fiber grating external cavity lasers; laser diode; leakage current induced distortion; modulation performance; noise; nulls; package parasitics; phase coupling; semiconductor laser diodes; signal flow graph; small-signal modulation conditions; small-signal regime; static conditions; strong feedback external cavity; Fiber gratings; Fiber lasers; Harmonic analysis; Interconnected systems; Laser modes; Laser noise; Leakage current; Packaging; Resonance; Resonant frequency;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.605670
