Title :
Femtosecond pulse generation from semiconductor lasers using the soliton-effect compression technique
Author :
Ahmed, Khawaja Aamer ; Chan, Kai Choong ; Liu, Hai-Feng
Author_Institution :
Dept. of Electr. & Electron. Eng., Melbourne Univ., Parkville, Vic., Australia
fDate :
6/1/1995 12:00:00 AM
Abstract :
An experimental investigation of various aspects associated with the pulse quality achieved by the soliton effect pulse compression technique is presented. By using fiber birefringence advantageously in conjunction with a wave plate and a polarizer, simultaneous pulse compression and pulse reshaping is realized and this can eliminate the pedestal component inherently associated with this compression technique. A train of 185-fs high-quality pedestal-free pulses, which are the shortest pulses ever achieved using semiconductor lasers, has been successfully generated. The detrimental effect of higher order dispersion on compression and its dependence on group velocity dispersion is also investigated. The results show that it is possible to minimize this effect by using fibers with an appropriate value of dispersion
Keywords :
birefringence; distributed feedback lasers; high-speed optical techniques; laser beams; laser feedback; optical fibre couplers; optical pulse compression; optical solitons; semiconductor lasers; 1.55 mum; 185 fs; femtosecond pulse generation; fiber birefringence; group velocity dispersion; high-quality pedestal-free pulses; higher order dispersion; pedestal component; polarizer; pulse compression; pulse compression technique; pulse reshaping; semiconductor lasers; soliton effect; soliton-effect compression technique; wave plate; Birefringence; Dispersion; Fiber lasers; Optical fiber polarization; Optical pulse compression; Optical pulse generation; Pulse compression methods; Pulse generation; Semiconductor lasers; Solitons;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.401246
