Optical Spiking Neurons Enable High-Speed and Energy-Efficient Optical Neural Networks

arXiv - PHYS - Optics Pub Date : 2024-09-09 DOI:arxiv-2409.05726

Bo Xu, Zefeng Huang, Yuetong Fang, Xin Wang, Bojun Cheng, Shaoliang Yu, Zhongrui Wang, Renjing Xu

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Abstract

Optical neural networks (ONNs) perform extensive computations using photons instead of electrons, resulting in passively energy-efficient and low-latency computing. Among various ONNs, the diffractive optical neural networks (DONNs) particularly excel in energy efficiency, bandwidth, and parallelism, therefore attract considerable attention. However, their performance is limited by the inherent constraints of traditional frame-based sensors, which process and produce dense and redundant information at low operating frequency. Inspired by the spiking neurons in human neural system, which utilize a thresholding mechanism to transmit information sparsely and efficiently, we propose integrating a threshold-locking method into neuromorphic vision sensors to generate sparse and binary information, achieving microsecond-level accurate perception similar to human spiking neurons. By introducing novel Binary Dual Adaptive Training (BAT) and Optically Parallel Mixture of Experts (OPMoE) inference methods, the high-speed, spike-based diffractive optical neural network (S2NN) demonstrates an ultra-fast operating speed of 3649 FPS, which is 30 fold faster than that of reported DONNs, delivering a remarkable computational speed of 417.96 TOPS and a system energy efficiency of 12.6 TOPS/W. Our work demonstrates the potential of incorporating neuromorphic architecture to facilitate optical neural network applications in real-world scenarios for both low-level and high-level machine vision tasks.

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光尖峰神经元实现了高速、高能效的光神经网络

光神经网络（ONNs）使用光子而非电子进行大量计算，从而实现了被动节能和低延迟计算。在各种光神经网络中，衍射光神经网络（DONN）在能效、带宽和并行性方面尤为突出，因此受到广泛关注。然而，传统的基于帧的传感器在低工作频率下处理和产生密集的冗余信息，其性能受到固有限制。受人类神经系统中利用阈值机制稀疏、高效地传输信息的尖峰神经元的启发，我们提出将阈值锁定方法集成到神经形态视觉传感器中，以生成稀疏的二进制信息，实现与人类尖峰神经元类似的微秒级精确感知。通过引入新颖的二进制双自适应训练（BAT）和光学并行专家混合（OPMoE）推理方法，基于尖峰的高速衍射光学神经网络（S2NN）实现了3649 FPS的超快运行速度，比已报道的DONNs快30倍，计算速度高达417.96 TOPS，系统能效为12.6TOPS/W。我们的工作证明了在现实世界场景中结合神经形态架构促进光学神经网络在低级和高级机器视觉任务中应用的潜力。

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arXiv - PHYS - Optics

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