Title :
Frequency-locking of a 1.3 mu m DFB laser using a miniature argon glow lamp
Author_Institution :
AT&T Bell Lab., Holmdel, NJ, USA
fDate :
6/1/1989 12:00:00 AM
Abstract :
The frequency of an InGaAsP distributed-feedback (DFB) laser was locked to the 2p/sub 10/-3d/sub 5/ transition of argon atoms at 1.2960 mu m using the optogalvanic signal obtained from a commercial miniature glow lamp. At a discharge current of 500 mu A, the signal-to-noise ratio of the optogalvanic signal corresponding to the Ar transition was about 18 dB. The peak-to-peak width of the first derivative signal was 650 MHz. The slope of the signal was 0.32 mu V/MHz near the center of the transition. By using the linear portion of the first-derivative signal, the laser frequency was locked to the Ar 2p/sub 10/-3d/sub 5/ transition. The peak-to-peak frequency fluctuations in the free-running condition were estimated to be 650 MHz, which is mainly due to laser temperature fluctuations. When the servo-loop was closed, the frequency stability was improved to better than 13 MHz.<>
Keywords :
III-V semiconductors; argon; discharge lamps; distributed feedback lasers; gallium arsenide; indium compounds; laser accessories; laser frequency stability; laser transitions; optogalvanic spectra; semiconductor junction lasers; 1.296 micron; 1.3 micron; 13 MHz; 500 muA; 650 MHz; Ar; Ar transition; DFB laser; InGaAsP; commercial miniature glow lamp; discharge current; distributed feedback laser semiconductor; free-running condition; frequency locking; frequency stability; laser frequency; laser temperature fluctuations; optogalvanic signal; peak-to-peak frequency fluctuations; servo-loop; signal-to-noise ratio; Argon; Atom lasers; Atomic beams; Fluctuations; Frequency estimation; Lamps; Laser transitions; Signal to noise ratio; Stability; Temperature;
Journal_Title :
Photonics Technology Letters, IEEE
