English

Learning Enabled Dense Space-division Multiplexing through a Single Multimode Fibre

Optics 2020-02-06 v1 Signal Processing

Abstract

Space-division multiplexing is a promising technology in optical fibre communication to improve the transmission capacity of a single optical fibre. However, the number of channels that can be multiplexed is limited by the crosstalks between channels, and the multiplexing is only applied to few-mode or multi-core fibres. Here, we propose a high-spatial-density channel multiplexing framework employing deep learning for standard multimode fibres (MMF). We present a proof-of-concept experimental system, consisting of a single light source, a single digital-micromirror-device modulator, a single detection camera, and a deep convolutional neural network (CNN) to demonstrate up to 400-channel simultaneous data transmission with accuracy close to 100% over MMFs of different types, diameters and lengths. A novel scalable semi-supervised learning model is proposed to adapt the CNN to the time-varying MMF information channels in real-time, to overcome the environmental changes such as temperature variations and vibrations, and to reconstruct the input data from complex crosstalks among hundreds of channels. This deep-learning based approach is promising to maximize the use of the spatial dimension of MMFs, and to break the present number-of-channel limit in space-division multiplexing for future high-capacity MMF transmission data links.

Keywords

Cite

@article{arxiv.2002.01788,
  title  = {Learning Enabled Dense Space-division Multiplexing through a Single Multimode Fibre},
  author = {Pengfei Fan and Michael Ruddlesden and Yufei Wang and Luming Zhao and Chao Lu and Lei Su},
  journal= {arXiv preprint arXiv:2002.01788},
  year   = {2020}
}
R2 v1 2026-06-23T13:31:55.393Z