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首页> 外文期刊>ACS applied materials & interfaces >Fully Printed All-Solid-State Organic Flexible Artificial Synapse for Neuromorphic Computing
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Fully Printed All-Solid-State Organic Flexible Artificial Synapse for Neuromorphic Computing

机译:完全印刷的全固态有机柔性人工突触,用于神经形态计算

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摘要

Nonvolatile, flexible artificial synapses that can be used for brain-inspired computing are highly desirable for emerging applications such as human-machine interfaces, soft robotics, medical implants, and biological studies. Printed devices based on organic materials are very promising for these applications due to their sensitivity to ion injection, intrinsic printability, biocompatibility, and great potential for flexible/stretchable electronics. Herein, we report the experimental realization of a nonvolatile artificial synapse using organic polymers in a scalable fabrication process. The three-terminal electrochemical neuromorphic device successfully emulates the key features of biological synapses: long-term potentiation/depression, spike timing-dependent plasticity learning rule, paired-pulse facilitation, and ultralow energy consumption. The artificial synapse network exhibits an excellent endurance against bending tests and enables a direct emulation of logic gates, which shows the feasibility of using them in futuristic hierarchical neural networks. Based on our demonstration of 100 distinct, nonvolatile conductance states, we achieved a high accuracy in pattern recognition and face classification neural network simulations.
机译:对于脑机启发的计算的非易失性,柔性人工突触对于新兴的应用是人机界面,软机器人,医疗植入物和生物学研究的新兴应用非常适望。由于它们对离子注射,内在印刷性,生物相容性,生物相容性以及柔性/可拉伸电子的巨大潜力,因此基于有机材料的印刷设备对于这些应用非常有前途。在此,我们在可伸缩制造过程中报告使用有机聚合物的非易失性人工突触的实验性实现。三末端电化学神经形状器件成功地模拟了生物突触的关键特征:长期增强/抑郁,尖峰时序依赖性塑性学习规则,配对脉冲便利化和超级能耗。人工突触网络对弯曲试验表现出优异的耐用性,并能够直接仿真逻辑门,这表明在未来派的层次神经网络中使用它们的可行性。基于我们100个不同的非易失性导电状态的演示,我们在模式识别和面部分类神经网络模拟中实现了高精度。

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  • 来源
    《ACS applied materials & interfaces》 |2019年第18期|共9页
  • 作者

    Liu Qingzhou; Liu Yihang; Li Ji; Lau Christian; Wu Fanqi; Zhang Anyi; Li Zhen; Chen Mingrui; Fu Hongyu; Draper Jeffrey; Cao Xuan; Zhou Chongwu;

  • 作者单位

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Ming Hsieh Dept Elect Engn Los Angeles CA 90089 USA;

    Univ Southern Calif Ming Hsieh Dept Elect Engn Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Ming Hsieh Dept Elect Engn Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Ming Hsieh Dept Elect Engn Los Angeles CA 90089 USA;

    Univ Southern Calif Ming Hsieh Dept Elect Engn Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

    Univ Southern Calif Mork Family Dept Chem Engn &

    Mat Sci Los Angeles CA 90089 USA;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 化学工业;
  • 关键词

    artificial synapses; neuromorphic computing; organic electronics; printed electronics; flexible electronics;

    机译:人工突触;神经形态计算;有机电子;印刷电子;柔性电子;

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