Communications Physics (Mar 2024)

Multiplexed orbital angular momentum beams demultiplexing using hybrid optical-electronic convolutional neural network

  • Jiachi Ye,
  • Haoyan Kang,
  • Qian Cai,
  • Zibo Hu,
  • Maria Solyanik-Gorgone,
  • Hao Wang,
  • Elham Heidari,
  • Chandraman Patil,
  • Mohammad-Ali Miri,
  • Navid Asadizanjani,
  • Volker Sorger,
  • Hamed Dalir

DOI
https://doi.org/10.1038/s42005-024-01571-3
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 7

Abstract

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Abstract Advancements in optical communications have increasingly focused on leveraging spatial-structured beams such as orbital angular momentum (OAM) beams for high-capacity data transmission. Conventional electronic convolutional neural networks exhibit constraints in efficiently demultiplexing OAM signals. Here, we introduce a hybrid optical-electronic convolutional neural network that is capable of completing Fourier optics convolution and realizing intensity-recognition-based demultiplexing of multiplexed OAM beams under variable simulated atmospheric turbulent conditions. The core part of our demultiplexing system includes a 4F optics system employing a Fourier optics convolution layer. This optical spatial-filtering-based convolutional neural network is utilized to realize the training and demultiplexing of the 4-bit OAM-coded signals under simulated atmospheric turbulent conditions. The current system shows a demultiplexing accuracy of 72.84% under strong turbulence scenarios with 3.2 times faster training time than all electronic convolutional neural networks.