Optical neural network via loose neuron array and functional learning

This research proposes a deep-learning paradigm, termed functional learning (FL), to physically train a loose neuron array, a group of non-handcrafted, non-differentiable, and loosely connected physical neurons whose connections and gradients are beyond explicit expression. The paradigm targets trai...

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Bibliographic Details
Published in:Nature communications 2023-05, Vol.14 (1), p.2535-2535, Article 2535
Main Authors: Huo, Yuchi, Bao, Hujun, Peng, Yifan, Gao, Chen, Hua, Wei, Yang, Qing, Li, Haifeng, Wang, Rui, Yoon, Sung-Eui
Format: Article
Language:English
Subjects:
639/624/1075/401
639/705/117
639/705/794
Arrays
Bandwidths
Deep learning
Fabrication
Forging
Hardware
Humanities and Social Sciences
Inference
Information processing
Learning
Light
Light speed
multidisciplinary
Neural networks
Neurons
Science
Science (multidisciplinary)
Training
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Summary:This research proposes a deep-learning paradigm, termed functional learning (FL), to physically train a loose neuron array, a group of non-handcrafted, non-differentiable, and loosely connected physical neurons whose connections and gradients are beyond explicit expression. The paradigm targets training non-differentiable hardware, and therefore solves many interdisciplinary challenges at once: the precise modeling and control of high-dimensional systems, the on-site calibration of multimodal hardware imperfectness, and the end-to-end training of non-differentiable and modeless physical neurons through implicit gradient propagation. It offers a methodology to build hardware without handcrafted design, strict fabrication, and precise assembling, thus forging paths for hardware design, chip manufacturing, physical neuron training, and system control. In addition, the functional learning paradigm is numerically and physically verified with an original light field neural network (LFNN). It realizes a programmable incoherent optical neural network, a well-known challenge that delivers light-speed, high-bandwidth, and power-efficient neural network inference via processing parallel visible light signals in the free space. As a promising supplement to existing power- and bandwidth-constrained digital neural networks, light field neural network has various potential applications: brain-inspired optical computation, high-bandwidth power-efficient neural network inference, and light-speed programmable lens/displays/detectors that operate in visible light. Here the authors have realized a programmable incoherent optical neural network that delivers light-speed, high-bandwidth, and power-efficient neural network inference via processing parallel visible light signals in the free space.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-023-37390-3