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A Deep Learning Approach to Universal Binary Visible Light Communication Transceiver

Information Theory 2019-10-29 v1 Machine Learning math.IT

Abstract

This paper studies a deep learning (DL) framework for the design of binary modulated visible light communication (VLC) transceiver with universal dimming support. The dimming control for the optical binary signal boils down to a combinatorial codebook design so that the average Hamming weight of binary codewords matches with arbitrary dimming target. An unsupervised DL technique is employed for obtaining a neural network to replace the encoder-decoder pair that recovers the message from the optically transmitted signal. In such a task, a novel stochastic binarization method is developed to generate the set of binary codewords from continuous-valued neural network outputs. For universal support of arbitrary dimming target, the DL-based VLC transceiver is trained with multiple dimming constraints, which turns out to be a constrained training optimization that is very challenging to handle with existing DL methods. We develop a new training algorithm that addresses the dimming constraints through a dual formulation of the optimization. Based on the developed algorithm, the resulting VLC transceiver can be optimized via the end-to-end training procedure. Numerical results verify that the proposed codebook outperforms theoretically best constant weight codebooks under various VLC setups.

Keywords

Cite

@article{arxiv.1910.12048,
  title  = {A Deep Learning Approach to Universal Binary Visible Light Communication Transceiver},
  author = {Hoon Lee and Tony Q. S. Quek and Sang Hyun Lee},
  journal= {arXiv preprint arXiv:1910.12048},
  year   = {2019}
}

Comments

to appear in IEEE Trans. Wireless Commun

R2 v1 2026-06-23T11:55:38.428Z