光子学
计算机科学
相变存储器
非易失性存储器
电子工程
材料科学
光电子学
计算机硬件
工程类
纳米技术
图层(电子)
作者
Maoliang Wei,Junying Li,Zequn Chen,Bo Tang,Zhiqi Jia,Peng Zhang,Kunhao Lei,Kai Xu,Jianghong Wu,Chuyu Zhong,Hui Ma,Yuting Ye,Jialing Jian,Chunlei Sun,Ruonan Liu,Ying Sun,Wei E. I. Sha,Xiaoyong Hu,Jianyi Yang,Lan Li
出处
期刊:Advanced photonics
[SPIE - International Society for Optical Engineering]
日期:2023-07-18
卷期号:5 (04)
被引量:85
标识
DOI:10.1117/1.ap.5.4.046004
摘要
Optical neural networks (ONNs), enabling low latency and high parallel data processing without electromagnetic interference, have become a viable player for fast and energy-efficient processing and calculation to meet the increasing demand for hash rate. Photonic memories employing nonvolatile phase-change materials could achieve zero static power consumption, low thermal cross talk, large-scale, and high-energy-efficient photonic neural networks. Nevertheless, the switching speed and dynamic energy consumption of phase-change material-based photonic memories make them inapplicable for in situ training. Here, by integrating a patch of phase change thin film with a PIN-diode-embedded microring resonator, a bifunctional photonic memory enabling both 5-bit storage and nanoseconds volatile modulation was demonstrated. For the first time, a concept is presented for electrically programmable phase-change material-driven photonic memory integrated with nanosecond modulation to allow fast in situ training and zero static power consumption data processing in ONNs. ONNs with an optical convolution kernel constructed by our photonic memory theoretically achieved an accuracy of predictions higher than 95% when tested by the MNIST handwritten digit database. This provides a feasible solution to constructing large-scale nonvolatile ONNs with high-speed in situ training capability.
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