English

Deep Neural Network-aided Soft-Demapping in Optical Coherent Systems: Regression versus Classification

Signal Processing 2022-08-23 v5

Abstract

We examine here what type of predictive modelling, classification, or regression, using neural networks (NN), fits better the task of soft-demapping based post-processing in coherent optical communications, where the transmission channel is nonlinear and dispersive. For the first time, we present possible drawbacks in using each type of predictive task in a machine learning context, considering the nonlinear coherent optical channel equalization/soft-demapping problem. We study two types of equalizers based on the feed-forward and recurrent NNs, for several transmission scenarios, in linear and nonlinear regimes of the optical channel. We point out that even though from the information theory perspective the cross-entropy loss (classification) is the most suitable option for our problem, the NN models based on the cross-entropy loss function can severely suffer from learning problems. The latter translates into the fact that regression-based learning is typically superior in terms of delivering higher Q-factor and achievable information rates. In short, we show by empirical evidence that loss functions based on cross-entropy may not be necessarily the most suitable option for training communication systems in practical scenarios when overfitting- and vanishing gradients-related problems come into play.

Keywords

Cite

@article{arxiv.2109.13843,
  title  = {Deep Neural Network-aided Soft-Demapping in Optical Coherent Systems: Regression versus Classification},
  author = {Pedro J. Freire and Jaroslaw E. Prilepsky and Yevhenii Osadchuk and Sergei K. Turitsyn and Vahid Aref},
  journal= {arXiv preprint arXiv:2109.13843},
  year   = {2022}
}
R2 v1 2026-06-24T06:26:49.811Z