DocumentCode
819087
Title
High-frequency broad-band signal generation using a semiconductor laser with a chaotic optical injection
Author
Uchida, Atsushi ; Heil, Tilmann ; Liu, Yun ; Davis, Peter ; Aida, Tahito
Author_Institution
ATR Adaptive Commun. Res. Labs., Kyoto, Japan
Volume
39
Issue
11
fYear
2003
Firstpage
1462
Lastpage
1467
Abstract
Chaotic signals with a flat power spectrum over 20 GHz have been generated using two commercially available semiconductor lasers coupled in a unidirectional master-slave scheme. The master laser has an external optical feedback that induces optical chaos in the laser output. A part of the chaotic light output from the master laser is injected into the slave laser. We experimentally demonstrated the generation of broad-band signals up to 22 GHz using lasers whose relaxation oscillation frequency in the free-running state is only around 6.4 GHz. We also show that the experimental results can be well reproduced by numerical simulations using two coupled rate equations. The numerical investigation shows that the high-frequency broad-band signal generation is owing to two key effects: high-frequency oscillations as a result of beating between the master and slave laser lights, and spectrum flattening due to the injection of the chaotic signal. The flatness, stability, and tunability of the power spectra demonstrated in our experiments suggests that the proposed system can be potentially useful for generation of high-frequency broad-band random signals.
Keywords
chaos generators; distributed feedback lasers; laser feedback; laser frequency stability; laser theory; laser tuning; optical chaos; semiconductor lasers; 22 GHz; 6.4 GHz; beating; chaotic optical injection; chaotic signals; coupled rate equations; distributed feedback semiconductor lasers; external optical feedback; flat power spectrum; flatness; free-running state; high-frequency broad-band signal generation; high-frequency oscillations; laser output; master laser; numerical simulations; optical chaos; relaxation oscillation frequency; semiconductor laser; slave laser; spectrum flattening; stability; tunability; unidirectional master-slave scheme; Chaos; Frequency; Laser feedback; Master-slave; Optical coupling; Optical feedback; Power generation; Power lasers; Semiconductor lasers; Signal generators;
fLanguage
English
Journal_Title
Quantum Electronics, IEEE Journal of
Publisher
ieee
ISSN
0018-9197
Type
jour
DOI
10.1109/JQE.2003.818281
Filename
1242366
Link To Document