Title :
Pulse-train uniformity in optical fiber lasers passively mode-locked by nonlinear polarization rotation
Author :
Kim, A.D. ; Kutz, J.N. ; Muraki, D.J.
Author_Institution :
Dept. of Appl. Math., Washington Univ., Seattle, WA, USA
fDate :
4/1/2000 12:00:00 AM
Abstract :
The generation of uniform soliton pulse trains by additive pulse mode locking has been experimentally demonstrated in a birefringent fiber laser with a passive polarizer. Numerical simulations of pulse propagation around such a fiber loop are presented which reveal that this mode-locking scheme does not result in strictly uniform pulse trains. Rather, the train of output pulses exhibits periodic fluctuations in intensity and polarization. A model for the pulse dynamics is developed which shows that these fluctuations depend on the strength of the fiber birefringence and the alignment of the polarizer with the fast- and slow-polarization axes of the fiber. It is also shown that increased uniformity of pulse trains is achieved with near alignment of the polarizer with the slow axis of the birefringence.
Keywords :
birefringence; fibre lasers; laser mode locking; optical fibre polarisation; optical pulse generation; optical solitons; birefringent fiber laser; fast-polarization fiber axis; fiber loop; nonlinear polarization rotation; numerical simulations; optical fiber lasers; passive mode-locking; passive polarizer; periodic fluctuations; pulse dynamics model; pulse propagation; pulse train intensity; pulse train polarization; pulse-train uniformity; slow-polarization fiber axis; uniform soliton pulse train generation; Birefringence; Fiber lasers; Fluctuations; Laser mode locking; Numerical simulation; Optical fiber polarization; Optical fibers; Optical pulse generation; Optical pulses; Solitons;
Journal_Title :
Quantum Electronics, IEEE Journal of
