Title :
2R optical regeneration: an all-optical solution for BER improvement
Author :
Rochette, Martin ; Fu, Libin ; Ta´eed, Vahid ; Moss, David J. ; Eggleton, Benjamin J.
Author_Institution :
Sch. of Phys., Sydney Univ., NSW
Abstract :
We show both theoretically and experimentally that signal re-amplifying and reshaping (2R) optical regenerator based on self-phase-modulation (SPM)-induced spectral broadening followed by optical filtering has significant advantages over conventional 2R regenerators. By discriminating amplified spontaneous emission noise from a pulsed signal, the SPM-based regenerator is able to selectively attenuate noise more than the pulsed signal. This unique feature results in a direct improvement in bit-error ratio (BER) of a noisy pulsed signal, whereas conventional 2R regenerators can only prevent BER degradation-not actually improve it. We compare the two classes of regenerator and highlight their fundamental differences. We also demonstrate the BER improvement of a noisy signal filtered with an SPM-based regenerator that utilizes a highly nonlinear silica fiber, and present a compact version by exploiting a short length of As2Se3 chalcogenide glass fiber
Keywords :
chalcogenide glasses; error statistics; glass fibres; optical filters; optical repeaters; self-phase modulation; spectral line broadening; superradiance; 2R optical regeneration; BER; amplified spontaneous emission noise; chalcogenide glass fiber; highly nonlinear silica fiber; optical filtering; reamplifying; reshaping; self-phase-modulation; spectral broadening; Bit error rate; Fiber nonlinear optics; Nonlinear optics; Optical attenuators; Optical filters; Optical noise; Optical pulses; Pulse amplifiers; Repeaters; Stimulated emission; Nonlinear optics; optical noise; optical pulse shaping; optical signal processing;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2006.876611
