English

Efficient data transport over multimode light-pipes with Megapixel images using differentiable ray tracing and Machine-learning

Optics 2023-08-25 v3 Artificial Intelligence Computer Vision and Pattern Recognition

Abstract

Retrieving images transmitted through multi-mode fibers is of growing interest, thanks to their ability to confine and transport light efficiently in a compact system. Here, we demonstrate machine-learning-based decoding of large-scale digital images (pages), maximizing page capacity for optical storage applications. Using a millimeter-sized square cross-section waveguide, we image an 8-bit spatial light modulator, presenting data as a matrix of symbols. Normally, decoders will incur a prohibitive O(n^2) computational scaling to decode n symbols in spatially scrambled data. However, by combining a digital twin of the setup with a U-Net, we can retrieve up to 66 kB using efficient convolutional operations only. We compare trainable ray-tracing-based with eigenmode-based twins and show the former to be superior thanks to its ability to overcome the simulation-to-experiment gap by adjusting to optical imperfections. We train the pipeline end-to-end using a differentiable mutual-information estimator based on the von-Mises distribution, generally applicable to phase-coding channels.

Keywords

Cite

@article{arxiv.2301.06496,
  title  = {Efficient data transport over multimode light-pipes with Megapixel images using differentiable ray tracing and Machine-learning},
  author = {Joowon Lim and Jannes Gladrow and Douglas Kelly and Greg O'Shea and Govert Verkes and Ioan Stefanovici and Sebastian Nowozin and Benn Thomsen},
  journal= {arXiv preprint arXiv:2301.06496},
  year   = {2023}
}

Comments

21 pages, 5 figures

R2 v1 2026-06-28T08:12:43.348Z