English

Deep-learning Autoencoder for Coherent and Nonlinear Optical Communication

Information Theory 2020-06-30 v2 Signal Processing math.IT

Abstract

Motivated by the recent success of end-to-end training of communications in the wireless domain, we strive to adapt the end-to-end-learning idea from the wireless case (i.e., linear) to coherent optical fiber links (i.e., nonlinear). Although, at first glance, it sounds like a straightforward extension, it turns out that several pitfalls exist - in terms of theory but also in terms of practical implementation. This paper analyzes the potential of an autoencoder and limitations for the optical fiber under the influence of Kerr-nonlinearity and chromatic dispersion. As there is no exact capacity limit known and, hence, no analytical perfect system solution available, we set great value to the interpretability on the learnings of the autoencoder. Therefore, we design its architecture to be as close as possible to the structure of a classic communication system, knowing that this may limit its degree of freedom and, thus, its performance. Nevertheless, we were able to achieve an unexpected high gain in terms of spectral efficiency compared to a conventional reference system.

Keywords

Cite

@article{arxiv.2006.15027,
  title  = {Deep-learning Autoencoder for Coherent and Nonlinear Optical Communication},
  author = {Tim Uhlemann and Sebastian Cammerer and Alexander Span and Sebastian Dörner and Stephan ten Brink},
  journal= {arXiv preprint arXiv:2006.15027},
  year   = {2020}
}

Comments

Accepted (21.02.2020) for presentation at the 21st IEEE/ITG-Symposium on Photonic Networks, Leipzig, Germany, 13-14.05.2020

R2 v1 2026-06-23T16:39:11.240Z