Title :
Advanced DSP for 400 Gb/s and Beyond Optical Networks
Author :
Xiang Zhou ; Nelson, Lynn
Author_Institution :
AT&T Labs., Middletown, NJ, USA
Abstract :
This paper presents a systematic review of several digital signal processing (DSP)-enabled technologies recently proposed and demonstrated for high spectral efficiency (SE) 400 Gb/s-class and beyond optical networks. These include 1) a newly proposed SE-adaptable optical modulation technology-time-domain hybrid quadrature amplitude modulation (QAM), 2) two advanced transmitter side digital spectral shaping technologies-Nyquist signaling (for spectrally-efficient multiplexing) and digital pre-equalization (for improving tolerance toward channel narrowing effects), and 3) a newly proposed training-assisted two-stage carrier phase recovery algorithm that is designed to address the detrimental cyclic phase slipping problem with minimal training overhead. Additionally, this paper presents a novel DSP-based method for mitigation of equalizer-enhanced phase noise impairments. It is shown that performance degradation caused by the interaction between the long-memory chromatic dispersion compensating filter/equalizer and local oscillator laser phase noise can be effectively mitigated by replacing the commonly used fast single-tap phase-rotation-based equalizer (for typical carrier phase recovery) with a fast multi-tap linear equalizer. Finally, brief reviews of two high-SE 400 Gb/s-class WDM transmission experiments employing these advanced DSP algorithms are presented.
Keywords :
equalisers; optical fibre dispersion; optical fibre networks; optical filters; optical modulation; optical transmitters; oscillators; phase noise; quadrature amplitude modulation; signal denoising; telecommunication channels; time-domain analysis; wavelength division multiplexing; DSP; Nyquist signaling; QAM; SE adaptable optical modulation technology; WDM channels; cyclic phase slipping problem; digital preequalization; digital signal processing; equalizer enhanced phase noise impairment mitigation; hybrid quadrature amplitude modulation; local oscillator laser phase noise mitigation; memory chromatic dispersion compensating filter; multitap linear equalizer; optical networks; single-tap phase rotation based equalizer; spectrally efficient multiplexing; time domain analysis; training assisted two-stage carrier phase recovery algorithm; transmitter side digital spectral shaping technology; Digital signal processing; Optical filters; Optical transmitters; Quadrature amplitude modulation; Time-domain analysis; Training; Carrier recovery; clock recovery; coherent; digital signal processing (DSP); equalization; equalizer-enhanced phase noise; fiber; hybrid QAM; modulation format; nyquist; optical transmission; phase recovery; pulse shaping; quadrature amplitude modulation (QAM); spectral efficiency (SE);
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2321135
