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Pushing the limits of optical information storage using deep learning

Applied Physics 2020-01-28 v2 Emerging Technologies Optics

Abstract

Diffraction drastically limits the bit density in optical data storage. To increase the storage density, alternative strategies involving supplementary recording dimensions and robust read-out schemes must be explored. Here, we propose to encode multiple bits of information in the geometry of subwavelength dielectric nanostructures. A crucial problem in high-density information storage concepts is the robustness of the information readout with respect to fabrication errors and experimental noise. Using a machine-learning based approach in which the scattering spectra are analyzed by an artificial neural network, we achieve quasi error free read-out of sequences of up to 9 bit, encoded in top-down fabricated silicon nanostructures. We demonstrate that probing few wavelengths instead of the entire spectrum is sufficient for robust information retrieval and that the readout can be further simplified, exploiting the RGB values from microscopy images. Our work paves the way towards high-density optical information storage using planar silicon nanostructures, compatible with mass-production ready CMOS technology.

Keywords

Cite

@article{arxiv.1805.03468,
  title  = {Pushing the limits of optical information storage using deep learning},
  author = {Peter R. Wiecha and Aurélie Lecestre and Nicolas Mallet and Guilhem Larrieu},
  journal= {arXiv preprint arXiv:1805.03468},
  year   = {2020}
}

Comments

13 pages, 6 figures + supporting informations of 25 pages, 37 figures

R2 v1 2026-06-23T01:49:31.182Z