Optical phase lock loop with a photorefractive optical beam combiner
- 1 October 1993
- journal article
- Published by Institute of Electrical and Electronics Engineers (IEEE) in IEEE Photonics Technology Letters
- Vol. 5 (10) , 1238-1240
- https://doi.org/10.1109/68.248440
Abstract
Two narrow linewidth Nd:YAG unidirectional nonplanar ring oscillator lasers were electronically phase locked using photorefractive two-wave mixing in an iron-doped indium phosphide (InP:Fe) crystal as an optical phase detector. The phase lock loop phase error signal was derived from a low-amplitude sinusoidal phase modulation signal impressed on the strong local oscillator beam at a frequency large compared to the inverse of the photorefractive-grating formation time. A 60-mW pump laser was phase locked to a 10-nW signal laser beam with an rms phase error less than 0.1 rad. No spatial mode matching, phase conjugate mirror configuration or optical coupling between the two laser cavities were required.Keywords
This publication has 9 references indexed in Scilit:
- Photorefractive two-wave mixing in the presence of high-speed optical phase modulationApplied Optics, 1993
- 193-mHz beat linewidth of frequency-stabilized laser-diode-pumped Nd:YAG ring lasersOptics Letters, 1993
- 50 Mbps optical homodyne communication receiver with a photorefractive optical beam combinerIEEE Photonics Technology Letters, 1992
- Wide-angle self-aligning heterodyning with four-wave mixingOptics Letters, 1991
- A 1320-nm experimental optical phase-locked loop: performance investigation and PSK homodyne experiments at 140 Mb/s and 2 Gb/sJournal of Lightwave Technology, 1990
- Theory of two-wave mixing gain enhancement in photorefractive InP:Fe: A new mechanism of resonanceJournal of Applied Physics, 1989
- Coherent optical detection through two-wave mixing in photorefractive materialsOptics Letters, 1988
- Amplification of high bandwidth signals through two-wave mixing in photorefractive Bi12SiO20 crystalsApplied Physics Letters, 1987
- Coupled-Wave Analysis of Holographic Storage in LiNbO3Journal of Applied Physics, 1972