DocumentCode
1527278
Title
Dynamic beam propagation method for flared semiconductor power amplifiers
Author
Balsamo, S. ; Sartori, F. ; Montrosset, I.
Author_Institution
Dipt. di Elettronica, Politecnico di Torino, Italy
Volume
2
Issue
2
fYear
1996
fDate
6/1/1996 12:00:00 AM
Firstpage
378
Lastpage
384
Abstract
In this paper, we present the results of a dynamic two-dimensional time-domain beam propagation method (two spatial dimensions plus time) for simulating travelling wave semiconductor optical amplifiers with nonuniform transverse section in pulsed regime. Using the effective refractive index method, the paraxial approximation and a moving timeframe, we reduce the scalar wave equation to a nonlinear parabolic partial differential equation for the slow complex envelope of the electric field. Diffraction, refractive index dispersion up to the second order, gain saturation and gain dispersion are included in the model. We numerically solve the equation through a locally one-dimensional (LOD) method employing both finite-difference techniques and FFT-based pseudospectral methods
Keywords
approximation theory; laser theory; light diffraction; optical hole burning; optical waveguide theory; partial differential equations; power amplifiers; refractive index; semiconductor device models; semiconductor lasers; time-domain analysis; waveguide lasers; FFT-based pseudospectral methods; dynamic beam propagation method; dynamic two-dimensional time-domain beam propagation method; effective refractive index method; electric field; finite-difference techniques; flared semiconductor power amplifiers; gain dispersion; gain saturation; light diffraction; moving timeframe; nonlinear parabolic partial differential equation; nonuniform transverse section; paraxial approximation; pulsed regime; refractive index dispersion; scalar wave equation; second order; slow complex envelope; spatial dimensions; travelling wave semiconductor optical amplifier simulation; Finite difference methods; Nonlinear equations; Optical diffraction; Optical propagation; Optical pulses; Partial differential equations; Pulse amplifiers; Refractive index; Semiconductor optical amplifiers; Time domain analysis;
fLanguage
English
Journal_Title
Selected Topics in Quantum Electronics, IEEE Journal of
Publisher
ieee
ISSN
1077-260X
Type
jour
DOI
10.1109/2944.577398
Filename
577398
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