利用光子神经细胞自动机进行深度学习

IF 20.6 Q1 OPTICS
Gordon H. Y. Li, Christian R. Leefmans, James Williams, Robert M. Gray, Midya Parto, Alireza Marandi
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引用次数: 0

摘要

过去十年间,深度学习技术突飞猛进,催生了对高效、可扩展硬件的无限需求。光子学利用光的独特特性,提供了一种前景广阔的解决方案。然而,传统的神经网络架构通常需要密集的可编程连接,这给光子实现带来了一些实际挑战。为了克服这些限制,我们提出并在实验中演示了光子神经细胞自动机(PNCA),用于具有稀疏连接的光子深度学习。PNCA 利用光子学的速度和互联性,以及细胞自动机通过局部交互实现自组织的特性,从而实现稳健、可靠和高效的处理。我们利用线性光干涉和参数非线性光学技术,在时间多路复用光子网络中进行全光计算,从而在实验中实现自组织图像分类。我们展示了仅使用 3 个可编程光子参数的二元(两类)图像分类,实现了较高的实验准确性,还能识别分布外数据。所提出的 PNCA 方法可适用于各种现有光子硬件,通过最大限度地发挥光基计算的优势,同时减轻其实际挑战,为传统光子神经网络提供了一个引人注目的替代方案。我们的成果展示了 PNCA 在推进光子深度学习方面的潜力,并为下一代光子计算机指明了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Deep learning with photonic neural cellular automata

Deep learning with photonic neural cellular automata

Rapid advancements in deep learning over the past decade have fueled an insatiable demand for efficient and scalable hardware. Photonics offers a promising solution by leveraging the unique properties of light. However, conventional neural network architectures, which typically require dense programmable connections, pose several practical challenges for photonic realizations. To overcome these limitations, we propose and experimentally demonstrate Photonic Neural Cellular Automata (PNCA) for photonic deep learning with sparse connectivity. PNCA harnesses the speed and interconnectivity of photonics, as well as the self-organizing nature of cellular automata through local interactions to achieve robust, reliable, and efficient processing. We utilize linear light interference and parametric nonlinear optics for all-optical computations in a time-multiplexed photonic network to experimentally perform self-organized image classification. We demonstrate binary (two-class) classification of images using as few as 3 programmable photonic parameters, achieving high experimental accuracy with the ability to also recognize out-of-distribution data. The proposed PNCA approach can be adapted to a wide range of existing photonic hardware and provides a compelling alternative to conventional photonic neural networks by maximizing the advantages of light-based computing whilst mitigating their practical challenges. Our results showcase the potential of PNCA in advancing photonic deep learning and highlights a path for next-generation photonic computers.

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来源期刊
Light-Science & Applications
Light-Science & Applications 数理科学, 物理学I, 光学, 凝聚态物性 II :电子结构、电学、磁学和光学性质, 无机非金属材料, 无机非金属类光电信息与功能材料, 工程与材料, 信息科学, 光学和光电子学, 光学和光电子材料, 非线性光学与量子光学
自引率
0.00%
发文量
803
审稿时长
2.1 months
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