Title :
Propagation equation based theory of intermodal injection locking in semiconductor lasers
Author :
Frey, R. ; Provost, J.G.
Author_Institution :
Lab. d´´Opt. Quantique, Ecole Polytech., Palaiseau, France
fDate :
10/1/1990 12:00:00 AM
Abstract :
Intermodal injection locking is analyzed theoretically through the use of propagation equations inside the amplifying semiconductor medium and the boundary conditions on the laser facets. In particular, the stability analysis is performed by considering the oscillation threshold of sideband waves generated inside the laser via intracavity nearly degenerate four-wave mixing processes. This study of injection locking is performed by taking into account the dispersion relationship of both the optical gain and linewidth enhancement factor. As a consequence, in intermodal injection locking, the injected-locked power is shown to be, in certain cases, lower than that of the free-running laser, and the frequency zones of stable injection locking broader than those obtained in the intramodal injection-locking case usually considered
Keywords :
laser cavity resonators; laser modes; laser theory; multiwave mixing; semiconductor junction lasers; spectral line breadth; amplifying semiconductor medium; boundary conditions; dispersion relationship; injected-locked power; intermodal injection locking; intracavity nearly degenerate four-wave mixing; laser facets; laser frequency stability; linewidth enhancement factor; optical gain; oscillation threshold; propagation equations; semiconductor lasers; sideband waves; stability analysis; stable injection locking frequency zone breadth; Boundary conditions; Dispersion; Equations; Four-wave mixing; Injection-locked oscillators; Laser stability; Laser theory; Optical propagation; Semiconductor lasers; Stability analysis;
Journal_Title :
Quantum Electronics, IEEE Journal of
