Kurtosis-Limited Sphere Shaping for Nonlinear Interference Noise Reduction in Optical Channels

Kurtosis-Limited Sphere Shaping for Nonlinear Interference Noise Reduction in Optical Channels

Nonlinear interference (NLI) generated during the propagation of an optical waveform through the fiber depends on the fourth order standardized moment of the channel input distribution, also known as kurtosis. Probabilistically-shaped inputs optimized for the linear Gaussian channel have a Gaussian-...

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Veröffentlicht in:Journal of lightwave technology 2022-01, Vol.40 (1), p.101-112
Hauptverfasser: Gultekin, Yunus Can, Alvarado, Alex, Vassilieva, Olga, Kim, Inwoong, Palacharla, Paparao, Okonkwo, Chigo M., Willems, Frans M. J.
Format: Artikel
Sprache:eng
Schlagworte:
Adaptive optics
Algorithms
amplitude shaping
AWGN channels
Channels
Forward error correction
Interference
Kurtosis
Noise propagation
Noise reduction
nonlinear interference
Nonlinear optics
Normal distribution
Optical fiber communication
Probabilistic shaping
Signal to noise ratio
Wave propagation
Waveforms
Wavelength division multiplexing
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Zusammenfassung:Nonlinear interference (NLI) generated during the propagation of an optical waveform through the fiber depends on the fourth order standardized moment of the channel input distribution, also known as kurtosis. Probabilistically-shaped inputs optimized for the linear Gaussian channel have a Gaussian-like distribution with high kurtosis. For optical channels, this leads to an increase in NLI power and consequently, a decrease in effective signal-to-noise ratio (SNR). In this work, we propose kurtosis-limited enumerative sphere shaping (K-ESS) as an algorithm to generate low-kurtosis shaped inputs. Numerical simulations at a shaping blocklength of 108 amplitudes demonstrate that with K-ESS, it is possible to increase the effective SNRs by 0.4 dB in a single-span single-channel scenario at 400 Gbit/s. K-ESS offers also a twofold decrease in frame error rate with respect to Gaussian-channel-optimal sphere shaping.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2021.3120915