Title :
Polarized Backward Raman Amplification in Randomly Birefringent Fibers
Author :
Galtarossa, Andrea ; Palmieri, Luca ; Santagiustina, Marco ; Ursini, Leonora
Author_Institution :
Dept. of Inf. Eng., Padova Univ.
Abstract :
In this paper, a model describing the vector interaction of an intense backward-propagating Raman pump and a weak forward-propagating Stokes signal in randomly birefringent fibers is proposed. The model accounts for the losses, the Raman interaction, and the linear and nonlinear birefringence. Realistic characteristics of the backward-propagation-birefringence vector have been originally accounted for. Numerical solutions show that polarized-backward-Raman amplifiers can have gain fluctuations larger than previously reported because of linear- and nonlinear-birefringence effects. Moreover, the gain mean depends on the signal and pump state of polarization imposed at the amplifier input or output. Simple formulas are derived for predicting the gain mean when nonlinear effects can be neglected
Keywords :
Raman lasers; birefringence; fluctuations; optical fibre amplifiers; optical fibre losses; optical fibre polarisation; optical pumping; Raman interaction; backward Raman amplification; backward-propagating Raman pump; backward-propagation-birefringence vector; birefringence effects; forward-propagating Stokes signal; gain fluctuations; linear birefringence; nonlinear birefringence; nonlinear effects; optical losses; polarized amplification; polarized-backward-Raman amplifiers; randomly birefringent fibers; vector interaction; Birefringence; Broadband amplifiers; Optical amplifiers; Optical fiber amplifiers; Optical fiber polarization; Optical pumping; Stimulated emission; US Department of Transportation; Vectors; Wavelength division multiplexing; Optical fiber amplifiers; Raman scattering; optical fiber polarization;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2006.883640
