Title :
Nonlinear Shannon Limit in Pseudolinear Coherent Systems
Author :
Mecozzi, Antonio ; Essiambre, René-Jean
Author_Institution :
Dept. of Electr. & Inf. Eng., Univ. of L´´Aquila, L´´Aquila, Italy
fDate :
6/15/2012 12:00:00 AM
Abstract :
In this paper, we develop a general first-order perturbation theory of the propagation of a signal in an optical fiber in the presence of amplification and Kerr nonlinearity, valid for arbitrary pulse shapes. We obtain a general expression of the sampled signal after optical filtering, coherent detection, and optimal sampling. We include intrachannel and as well as interchannel nonlinear effects. We obtain simplified expressions in the case in which the accumulated dispersion is high (equivalent to the far-field limit in paraxial optics). This general theory is applied in detail to the special case of spectral-efficient sinc pulses. This exercise shows that the characteristics of the neighboring wavelength-division multiplexed channels are essential in determining the nonlinear impairments.
Keywords :
amplification; optical Kerr effect; optical fibre dispersion; optical fibre filters; perturbation theory; wavelength division multiplexing; Kerr nonlinearity; accumulated dispersion; amplification; arbitrary pulse shapes; coherent detection; far-field limit; general expression; general first-order perturbation theory; intrachannel nonlinear effects; nonlinear Shannon limit; nonlinear impairments; optical fiber; optical filtering; optimal sampling; paraxial optics; pseudolinear coherent systems; signal propagation; spectral-efficient sine pulses; wavelength-division multiplexed channels; Dispersion; Noise; Nonlinear optics; Optical pulse shaping; Optical receivers; Optical transmitters; Wavelength division multiplexing; Capacity; optical nonlinearities;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2012.2190582
