Title :
Performance predictions for vertical-cavity semiconductor laser amplifiers
Author :
Tombling, Craig ; Saitoh, Tadashi ; Mukai, Takaaki
fDate :
11/1/1994 12:00:00 AM
Abstract :
Vertical-cavity surface-emitting laser structures are studied theoretically to examine their potential for optical amplification. The major advantages of such a device are the minimal insertion loss and the polarization insensitivity of the gain which the transverse geometry provides. Although single-pass gain is necessarily low owing to a short optical cavity, operation as a Fabry-Perot amplifier in either the reflection or transmission mode ran provide high-performance characteristics. A comparison between edge- and surface-emitting amplifiers shows where advantageous operation can be obtained, and suggests how the best use of the surface-emitting amplifier performance can be made. By considering contrasting device dimensions, we show that gain, saturation output power, and noise characteristics suitable for both fiber optic and array processing configurations are readily attainable
Keywords :
Fabry-Perot resonators; laser cavity resonators; laser noise; light polarisation; optical losses; optical saturation; semiconductor device noise; surface emitting lasers; Fabry-Perot amplifier; array processing configurations; device dimensions; edge-emitting amplifiers; fiber optic processing configurations; high-performance characteristics; minimal insertion loss; noise characteristics; optical amplification; polarization insensitivity; reflection mode; saturation output power; short optical cavity; single-pass gain; surface-emitting amplifier performance; surface-emitting amplifiers; transmission mode; transverse geometry; vertical-cavity semiconductor laser amplifiers; vertical-cavity surface-emitting laser structures; Insertion loss; Laser theory; Operational amplifiers; Optical amplifiers; Optical losses; Optical polarization; Semiconductor lasers; Stimulated emission; Surface emitting lasers; Vertical cavity surface emitting lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
