English

All-Chalcogenide Programmable All-Optical Deep Neural Networks

Optics 2021-03-02 v3 Emerging Technologies

Abstract

Deeplearning algorithms are revolutionising many aspects of modern life. Typically, they are implemented in CMOS-based hardware with severely limited memory access times and inefficient data-routing. All-optical neural networks without any electro-optic conversions could alleviate these shortcomings. However, an all-optical nonlinear activation function, which is a vital building block for optical neural networks, needs to be developed efficiently on-chip. Here, we introduce and demonstrate both optical synapse weighting and all-optical nonlinear thresholding using two different effects in a chalcogenide material photonic platform. We show how the structural phase transitions in a wide-bandgap phase-change material enables storing the neural network weights via non-volatile photonic memory, whilst resonant bond destabilisation is used as a nonlinear activation threshold without changing the material. These two different transitions within chalcogenides enable programmable neural networks with near-zero static power consumption once trained, in addition to picosecond delays performing inference tasks not limited by wire charging that limit electrical circuits; for instance, we show that nanosecond-order weight programming and near-instantaneous weight updates enable accurate inference tasks within 20 picoseconds in a 3-layer all-optical neural network. Optical neural networks that bypass electro-optic conversion altogether hold promise for network-edge machine learning applications where decision-making in real-time are critical, such as for autonomous vehicles or navigation systems such as signal pre-processing of LIDAR systems.

Keywords

Cite

@article{arxiv.2102.10398,
  title  = {All-Chalcogenide Programmable All-Optical Deep Neural Networks},
  author = {Ting Yu and Xiaoxuan Ma and Ernest Pastor and Jonathan K. George and Simon Wall and Mario Miscuglio and Robert E. Simpson and Volker J. Sorger},
  journal= {arXiv preprint arXiv:2102.10398},
  year   = {2021}
}
R2 v1 2026-06-23T23:21:31.453Z