Title :
Simulation of phase modulation in EDFAs using an extended model
Author :
Reichel, S. ; Lenz, W. ; Zengerle, R.
Author_Institution :
Dept. of Electromagn. & Opt. Commun., Kaiserslautern Univ., Germany
Abstract :
Nowadays, erbium-doped fiber amplifiers are described by the rate equations for the population densities and the evolution equations of the optical power propagation in the fiber. Since only the power is considered, phase effects like phase modulation and dispersion are not addressed. Here, we present an extended model using a slowly varying envelope approximation that takes into account dispersion and phase modulation. The phase modulation shifts the carrier frequency to a higher frequency. Due to this effect the impulse experiences in a single-mode fiber a different dispersion and, therefore, it should be included for numerical simulations.
Keywords :
approximation theory; electro-optical modulation; erbium; fibre lasers; laser theory; phase modulation; EDFAs; dispersion; erbium-doped fiber amplifiers; evolution equations; extended model; higher frequency; numerical simulations; optical power propagation; phase effects; phase modulation; population densities; rate equations; slowly varying envelope approximation; Eigenvalues and eigenfunctions; Electromagnetic propagation; Erbium-doped fiber amplifier; Frequency; Maxwell equations; Optical attenuators; Optical fiber communication; Optical fiber dispersion; Optical propagation; Phase modulation;
Journal_Title :
Photonics Technology Letters, IEEE
