Intelligent neuromorphic computing based on nanophotonics and metamaterials

IF 1.8 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

MRS Communications Pub Date : 2024-02-08 DOI:10.1557/s43579-024-00520-z

Qian Ma, Xinxin Gao, Ze Gu, Che Liu, Lianlin Li, Jian Wei You, Tie Jun Cui

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Abstract

With the rapid development of artificial intelligence and computing chips approaching the bottleneck of power consumption and computing power, the research on intelligent computing hardware with high speed and high energy efficiency is an important trend. Recently, neuromorphic computing represented by photonic circuit neural networks and all-optical diffraction neural networks has attracted widespread attention due to their ultra-fast and ultra-efficient computing architectures. In this perspective, we first review some representative works and introduce them through two main lines of planar photonic circuit neural networks and three-dimensional diffraction neural networks to compare their characteristics and performance. We further discuss programmable designs for neuromorphic computing hardware, which bring it closer to general-purpose computing devices. Besides intelligent neural networks in the optical band, we also review the development and application of the diffractive neural networks in the microwave band, showing their programmable capabilities. Finally, we present the future directions and development trends of intelligent neuromorphic computing and its potential applications in wireless communications, information processing, and sensing.

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基于纳米光子学和超材料的智能神经形态计算

随着人工智能的飞速发展，计算芯片逐渐逼近功耗和计算能力的瓶颈，研究高速、高能效的智能计算硬件成为重要趋势。近年来，以光子电路神经网络和全光衍射神经网络为代表的神经形态计算因其超快、超高效的计算架构而受到广泛关注。从这个角度出发，我们首先回顾了一些有代表性的工作，并通过平面光子电路神经网络和三维衍射神经网络两条主线来介绍它们，比较它们的特点和性能。我们进一步讨论了神经形态计算硬件的可编程设计，使其更接近通用计算设备。除了光波段的智能神经网络，我们还回顾了微波波段衍射神经网络的发展和应用，展示了它们的可编程能力。最后，我们介绍了智能神经形态计算的未来方向和发展趋势，及其在无线通信、信息处理和传感领域的潜在应用。

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来源期刊

MRS Communications MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

2.60

自引率

10.50%

发文量

166

审稿时长

>12 weeks

期刊介绍： MRS Communications is a full-color, high-impact journal focused on rapid publication of completed research with broad appeal to the materials community. MRS Communications offers a rapid but rigorous peer-review process and time to publication. Leveraging its access to the far-reaching technical expertise of MRS members and leading materials researchers from around the world, the journal boasts an experienced and highly respected board of principal editors and reviewers.