Title :
High-performance homodyne optical injection phase-lock loop using wide-linewidth semiconductor lasers
Author :
Bordonalli, A.C. ; Walton, C. ; Seeds, A.J.
Author_Institution :
Dept. of Electron. & Electr. Eng., Univ. Coll. London, UK
Abstract :
The requirements for narrow linewidth lasers and short loop propagation delay limit optical phase-lock loop realizability with semiconductor lasers is presented. Although optical injection locking can provide low-phase-error variance, its locking range is limited by stability considerations. The first experimental results for a new architecture combining both techniques, the optical injection phase-lock loop (OIPLL), are reported. Phase error variance values as low as 0.006 rad/sup 2/ (500 MHz bandwidth) and locking ranges exceeding 26 GHz are achieved using DFB lasers of summed linewidth 36 MHz with loop delay of 15 ns and injection ratio less than -30 dB.
Keywords :
distributed feedback lasers; errors; laser mode locking; laser stability; optical communication equipment; optical phase locked loops; semiconductor lasers; spectral line breadth; 15 ns; 500 MHz; DFB lasers; high-performance homodyne optical injection phase-lock loop; injection ratio; locking range; locking ranges; loop delay; low-phase-error variance; narrow linewidth lasers; optical injection locking; optical injection phase-lock loop; optical phase-lock loop realizability; phase error variance; semiconductor lasers; short loop propagation delay limit; stability considerations; summed linewidth; wide-linewidth semiconductor lasers; Fiber lasers; Laser beams; Master-slave; NIST; Optical coupling; Optical fiber polarization; Optical retarders; Petroleum; Propagation delay; Semiconductor lasers;
Journal_Title :
Photonics Technology Letters, IEEE
