Title :
Theory and simulation of the dynamics and stability of actively modelocked lasers
Author :
O´Neil, J.J. ; Kutz, J. Nathan ; Sandstede, Björn
Author_Institution :
Dept. of Appl. Math., Washington Univ., Seattle, WA, USA
fDate :
10/1/2002 12:00:00 AM
Abstract :
A new model is proposed for the active modulation component of a mode-locked laser cavity. By using Jacobi elliptic functions to capture the periodic forcing to the cavity, we are able to construct exact solutions representing a mode-locked pulse train. Two families of pulse-train solutions are generated: one in which neighboring pulses are in-phase and a second in which neighboring pulses are out-of-phase. We show that only out-of-phase solutions allow for stable mode-locked pulse trains. Further, pulse-to-pulse interactions can generate instabilities that destroy the pulse train altogether or lead to Q-switching.
Keywords :
Schrodinger equation; laser mode locking; laser stability; optical pulse generation; optical solitons; self-phase modulation; Jacobi elliptic functions; Kerr-induced self-phase modulation; active modulation component; chromatic dispersion; in-phase solutions; laser dynamics; laser instabilities; mode-locked laser cavity; mode-locked pulse train; nonlinear Schrodinger equation; out-of-phase solutions; periodic forcing; pulse-to-pulse interactions; Erbium-doped fiber lasers; Laser mode locking; Laser modes; Laser stability; Laser theory; Optical attenuators; Optical fiber polarization; Optical pulse generation; Optical pulses; Pulse amplifiers;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.802979
