Super-resolution diffractive neural network for all-optical direction of arrival estimation beyond diffraction limits

IF 20.6 Q1 OPTICS
Sheng Gao, Hang Chen, Yichen Wang, Zhengyang Duan, Haiou Zhang, Zhi Sun, Yuan Shen, Xing Lin
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Abstract

Wireless sensing of the wave propagation direction from radio sources lays the foundation for communication, radar, navigation, etc. However, the existing signal processing paradigm for the direction of arrival estimation requires the radio frequency electronic circuit to demodulate and sample the multichannel baseband signals followed by a complicated computing process, which places the fundamental limit on its sensing speed and energy efficiency. Here, we propose the super-resolution diffractive neural networks (S-DNN) to process electromagnetic (EM) waves directly for the DOA estimation at the speed of light. The multilayer meta-structures of S-DNN generate super-oscillatory angular responses in local angular regions that can perform the all-optical DOA estimation with angular resolutions beyond the diffraction limit. The spatial-temporal multiplexing of passive and reconfigurable S-DNNs is utilized to achieve high-resolution DOA estimation over a wide field of view. The S-DNN is validated for the DOA estimation of multiple radio sources over 5 GHz frequency bandwidth with estimation latency over two to four orders of magnitude lower than the state-of-the-art commercial devices in principle. The results achieve the angular resolution over an order of magnitude, experimentally demonstrated with four times, higher than diffraction-limited resolution. We also apply S-DNN’s edge computing capability, assisted by reconfigurable intelligent surfaces, for extremely low-latency integrated sensing and communication with low power consumption. Our work is a significant step towards utilizing photonic computing processors to facilitate various wireless sensing and communication tasks with advantages in both computing paradigms and performance over electronic computing.

Abstract Image

用于超越衍射极限的全光学到达方向估计的超分辨率衍射神经网络
对无线电波传播方向的无线传感为通信、雷达、导航等奠定了基础。然而,现有的到达方向估计信号处理范式需要射频电子电路对多通道基带信号进行解调和采样,然后进行复杂的计算处理,这从根本上限制了其传感速度和能效。在此,我们提出了超分辨率衍射神经网络(S-DNN),以光速直接处理电磁波(EM),进行 DOA 估计。S-DNN 的多层元结构可在局部角度区域产生超振荡角度响应,从而以超越衍射极限的角度分辨率执行全光 DOA 估计。利用无源和可重构 S-DNN 的时空复用技术,可在宽视场范围内实现高分辨率 DOA 估计。S-DNN 在 5 GHz 频率带宽上对多个无线电信号源的 DOA 估计进行了验证,其估计延迟原则上比最先进的商业设备低 2 到 4 个数量级。结果实现了超过一个数量级的角度分辨率,实验证明比衍射极限分辨率高出四倍。我们还应用了 S-DNN 的边缘计算能力,在可重构智能表面的辅助下,以低功耗实现了极低延迟的集成传感和通信。我们的工作是朝着利用光子计算处理器促进各种无线传感和通信任务迈出的重要一步,在计算模式和性能方面都比电子计算有优势。
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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
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803
审稿时长
2.1 months
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