Title :
Phase-Preserving Amplitude Regeneration in DPSK Transmission Systems Using a Nonlinear Amplifying Loop Mirror
Author :
Stephan, Christian ; Sponsel, Klaus ; Onishchukov, Georgy ; Schmauss, Bernhard ; Leuchs, Gerd
Author_Institution :
Max Planck Inst. for the Sci. of Light, Erlangen, Germany
Abstract :
A phase-preserving 2R regenerator based on a nonlinear amplifying loop mirror was implemented in a RZ-DPSK transmission system. Its performance has been investigated in numerical simulations and experimentally. The results show that amplitude regeneration using a NALM can efficiently prevent accumulation of nonlinear phase noise in a 10 Gb/s DPSK transmission system. In the experiments, significant improvements of eye opening and of BER as well as a 3 dB increase in fiber launch power have been demonstrated. Simulations at 10 Gb/s and 100 Gb/s indicated that the enhancement of the transmission quality is smaller at 100 Gb/s. The reason is that at 100 Gb/s nonlinear intra-channel effects rather than pure nonlinear phase noise are the main limiting factor and the NALM can only reduce the accumulation of amplitude noise in that case.
Keywords :
Sagnac interferometers; differential phase shift keying; error statistics; integrated optics; mirrors; nonlinear optics; optical fibre amplifiers; optical fibre couplers; optical fibre networks; phase noise; BER; RZ-DPSK transmission system; amplitude noise; asymmetrical fiber coupler; bidirectional fiber amplifier; bit rate 10 Gbit/s; bit rate 100 Gbit/s; highly nonlinear fiber; nonlinear amplifying loop mirror; nonlinear fiber Sagnac interferometer; nonlinear intra-channel effects; nonlinear phase noise; phase-preserving 2R regenerator; phase-preserving amplitude regeneration; Differential quadrature phase shift keying; Fiber nonlinear optics; Fluctuations; Mirrors; Noise level; Nonlinear optics; Optical distortion; Optical fiber couplers; Optical fiber polarization; Phase noise; 2R regeneration; Differential phase-shift keying; nonlinear amplifying loop mirror; nonlinear phase noise;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2009.2032369
