Title :
Nonlinear Electrical Equalization for Different Modulation Formats With Optical Filtering
Author :
Xia, Chunmin ; Rosenkranz, Werner
Author_Institution :
Kiel Univ.
fDate :
4/1/2007 12:00:00 AM
Abstract :
Based on bit-error-ratio simulations, we investigate electrical-dispersion-compensation performance by using a nonlinear electrical equalizer based on nonlinear Volterra theory for different modulation formats. This nonlinear equalizer is compared to conventional decision-feedback equalizer as well as to maximum-likelihood sequence estimation. Especially, we show that nonlinear equalizers, in conjunction with narrowband optical filtering of the light signal, result in improved performance. First of all, the system can benefit from the noise reduction due to narrowband filtering. Second, interacting with chromatic dispersion, nonlinear equalizers benefit from the improved dispersion tolerance through spectrum reshaping by narrowband optical filtering. Finally, nonlinear equalizers can efficiently mitigate the distortion resulting from strong optical filtering
Keywords :
Volterra equations; equalisers; error statistics; filtering theory; optical communication equipment; optical fibre communication; optical fibre dispersion; optical modulation; bit-error-ratio simulations; chromatic dispersion; decision-feedback equalizer; dispersion tolerance; electrical equalizer; electrical-dispersion compensation; maximum-likelihood sequence estimation; modulation formats; narrowband filtering; noise reduction; nonlinear Volterra theory; nonlinear electrical equalization; nonlinear equalizers; optical distortion; optical filtering; spectrum reshaping; Decision feedback equalizers; Filtering; Maximum likelihood estimation; Narrowband; Noise reduction; Nonlinear optics; Optical distortion; Optical filters; Optical modulation; Optical noise; Decision-feedback equalizer (DFE); Volterra theory; electrical-dispersion compensation (EDC); maximum-likelihood sequence estimation (MLSE); nonlinear equalizer; strong optical filtering;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2007.891174
