Title :
Electronic mitigation of fiber transmission impairment
Author_Institution :
Fac. of Eng., Ain Shams Univ., Cairo, Egypt
Abstract :
Dispersion and nonlinear wave impairment upon transition over single channel optical fiber are reviewed. Since chromatic dispersion can be predicted, transmit techniques are developed to contain its effects on digital signal transition. Advancements in these techniques are given high-lighting dispersion resilience versus electronic predistortion. The latter can also handle self phase modulation due to Kerr effect. Technologies for constant-envelope modulation formats are also considered for its resilience to nonlinear impairments. On the other hand, receiver techniques have drawn much attenuation in the last few years. Advanced receiver techniques are outlined. Optical equalization is given as a reference to its electronic version. Both analog and digital control strategies are considered. Feed forward and compensation-feedback equalization are outlined. The optimum receiver minimizes the error probability by selecting the most likely sequence. This is done by maximum likelihood sequence estimation (MLSE) Viterbi-like receiver with symbol rate sampling, preceded by a matched filter.
Keywords :
equalisers; error statistics; matched filters; maximum likelihood estimation; optical Kerr effect; optical fibre dispersion; optical modulation; phase modulation; Kerr effect; Viterbi-like receiver; analog control strategies; chromatic dispersion; compensation-feedback equalization; digital control strategies; digital signal transition; dispersion wave impairment; electronic mitigation; electronic predistortion; error probability; feedforward equalization; fiber transmission impairment; matched filter; maximum likelihood sequence estimation; nonlinear wave impairment; optical equalization; receiver techniques; self phase modulation; single channel optical fiber; symbol rate sampling; Chromatic dispersion; Kerr effect; Maximum likelihood estimation; Optical attenuators; Optical fiber dispersion; Optical fibers; Optical receivers; Phase modulation; Predistortion; Resilience;
Conference_Titel :
Radio Science Conference, 2009. NRSC 2009. National
Conference_Location :
New Cairo
Print_ISBN :
978-1-4244-4214-0
