Multi-frequency low-noise semiconductor laser sources enabling advancement of resonant fiber optic gyroscopes including performance over temperature

Émile Girard-Deschênes; François Costin; Simon Ayotte; André Babin; Katherine Légaré; Bruno Labranche; Laurent Dusablon; Jean-Sébastien Pelletier-Rioux; Patrick Dufour; Sébastien Deschênes; Rodrigo Falci; Ghislain Bilodeau; Philippe Chrétien; Charles-André Davidson; Dominique D'amato; Mathieu Laplante; Robert Baribault; Marc Smiciklas; Lee Strandjord; Chellappan Narayanan; Robert Compton; Glen Sanders

doi:10.1117/12.3000391

11 March 2024 Multi-frequency low-noise semiconductor laser sources enabling advancement of resonant fiber optic gyroscopes including performance over temperature

Émile Girard-Deschênes, François Costin, Simon Ayotte, André Babin, Katherine Légaré, Bruno Labranche, Laurent Dusablon, Jean-Sébastien Pelletier-Rioux, Patrick Dufour, Sébastien Deschênes, Rodrigo Falci, Ghislain Bilodeau, Philippe Chrétien, Charles-André Davidson, Dominique D'amato, Mathieu Laplante, Robert Baribault, Marc Smiciklas, Lee Strandjord, Chellappan Narayanan, Robert Compton, Glen Sanders

Author Affiliations +

Proceedings Volume 12893, Photonic Instrumentation Engineering XI; 128930A (2024) https://doi.org/10.1117/12.3000391
Event: SPIE OPTO, 2024, San Francisco, California, United States

Abstract

We present multi-frequency low-noise semiconductor laser sources for resonant fiber optic gyroscope (RFOG) interrogation that have enabled excellent gyro stability over temperature. Each laser source includes three distributed feedback semiconductor laser chips coupled with micro-lenses to multi-component silicon photonics (SiP) chips. A first laser, the master, is locked to the RFOG with a Pound-Drever-Hall loop. Two slave lasers are optically phase-locked to the master laser with electrical loop bandwidths of 100 MHz. The SiP chips perform beat note detection and several other functions, such as phase and intensity noise suppression. The lasers and SiP chips are packaged in an optical engine that is controlled by compact low noise electronics. The fiber pigtails are connected to the RFOG so that light is sent in clockwise and counterclockwise directions. Tracking of the RFOG resonance frequencies in both directions allows rotation sensing. An ultra-stable differential frequency noise floor of 0.05 Hz/rt-Hz was obtained between the lasers and the coil resonator which was instrumental in achieving results for the RFOG over 60˚ C operating temperature range. The corresponding angle random walk level is less than 0.01 ˚/rt-hr and was not limited by laser differential frequency noise. The gyroscope bias drift over the tested temperature range was maintained within 0.005 ˚/hr, the best-ever published RFOG performance over temperature to date.

Conference Presentation

(2024) Published by SPIE. Downloading of the abstract is permitted for personal use only.

Citation Download Citation

Émile Girard-Deschênes, François Costin, Simon Ayotte, André Babin, Katherine Légaré, Bruno Labranche, Laurent Dusablon, Jean-Sébastien Pelletier-Rioux, Patrick Dufour, Sébastien Deschênes, Rodrigo Falci, Ghislain Bilodeau, Philippe Chrétien, Charles-André Davidson, Dominique D'amato, Mathieu Laplante, Robert Baribault, Marc Smiciklas, Lee Strandjord, Chellappan Narayanan, Robert Compton, and Glen Sanders "Multi-frequency low-noise semiconductor laser sources enabling advancement of resonant fiber optic gyroscopes including performance over temperature", Proc. SPIE 12893, Photonic Instrumentation Engineering XI, 128930A (11 March 2024); https://doi.org/10.1117/12.3000391

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