Title :
Integrable multimode interference distributed Bragg reflector laser all-optical flip-flops
Author :
Raburn, Maura ; Takenaka, Mitsuru ; Takeda, Koji ; Song, Xueliang ; Barton, Jonathan S. ; Nakano, Yoshiaki
Author_Institution :
Infinera, Sunnyvale, CA
fDate :
7/1/2006 12:00:00 AM
Abstract :
A novel fully integrable all-optical flip-flop has been created using distributed Bragg reflector multimode interference bistable laser diodes. The single metal-organic vapor phase epitaxy regrowth offset quantum well structure active/passive integrated flip-flop lases in single mode at 1554 nm and is compatible with standard fabrication methods of InP photonic integrated circuits (PICs). All-optical reset switching through cross-gain saturation was demonstrated over a 52-nm range, at 1522-1574 nm. An optical set has been achieved with -3 dBm and optical reset with less than -5-dBm external light injection. The flip-flop will be useful for integration in PICs of future photonic systems for self-routing and optical memories or buffers
Keywords :
III-V semiconductors; distributed Bragg reflector lasers; flip-flops; indium compounds; integrated optics; light interference; optical bistability; optical saturation; optical storage; optical switches; quantum well lasers; vapour phase epitaxial growth; 1522 to 1574 nm; InP; InP photonic integrated circuits; all-optical flip-flops; all-optical reset switching; bistable laser diode; buffers; cross-gain saturation; distributed Bragg reflector laser; external light injection; integrable multimode interference laser; metal-organic vapor phase epitaxy regrowth; optical memories; photonic systems; quantum well structure; self-routing; Diode lasers; Distributed Bragg reflectors; Flip-flops; Interference; Laser modes; Optical bistability; Optical buffering; Optical saturation; Photonic integrated circuits; Quantum well lasers; Bistable laser diode (BLD); distributed Bragg reflector (DBR) lasers; flip-flop; gain saturation; multimode interference (MMI) coupler; optical memory;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.877569
