Title :
Self-Pulsating Amplified Feedback Laser Based on a Loss-Coupled DFB Laser
Author :
Yee, Dae-Su ; Leem, Young Ahn ; Kim, Sang-Taek ; Park, Kyung Hyun ; Kim, Boo-Gyoun
Author_Institution :
Korea Res. Inst. of Stand. & Sci., Daejeon
Abstract :
Monolithic self-pulsating semiconductor lasers called amplified feedback lasers (AFLs) can generate high-frequency self-pulsations according to the concept of a single-mode laser with shortly delayed optical feedback, which consist of a distributed-feedback (DFB) laser, a phase control, and an amplifier section. Since mode degeneracy of the DFB section, which should operate as a single-mode laser, affects the self-pulsation, single-mode characteristics of the DFB section are critical for the self-pulsation. The effect of a complex coupling in the DFB section on the self-pulsation is numerically analyzed to reveal that the complex coupling provides a wide operation range for the self-pulsation. Also, self-pulsating AFLs based on a loss-coupled DFB laser are experimentally demonstrated to verify the self-pulsation characteristics and the capability for all-optical clock recovery.
Keywords :
distributed feedback lasers; laser beams; laser feedback; laser modes; optical losses; optical pulse generation; semiconductor lasers; synchronisation; time-domain analysis; all-optical clock recovery; distributed-feedback laser; high-frequency self-pulsations; loss-coupled DFB laser; mode degeneracy; monolithic self-pulsating semiconductor lasers; optical feedback; self-pulsating amplified feedback laser; single-mode laser; time-domain model; Delay; Distributed amplifiers; Distributed feedback devices; Laser feedback; Laser modes; Optical feedback; Optical losses; Phase control; Semiconductor lasers; Semiconductor optical amplifiers; All-optical clock recovery; distributed feedback (DFB) lasers; optical feedback; self-pulsation; semiconductor lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2007.907194
