A Reconfigurable Graphene-Based Spiking Neural Network Architecture

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2021-07-07 DOI:10.1109/OJNANO.2021.3094761
He Wang;Nicoleta Cucu Laurenciu;Sorin Dan Cotofana
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引用次数: 1

Abstract

In the paper we propose a reconfigurable graphene-based Spiking Neural Network (SNN) architecture and a training methodology for initial synaptic weight values determination. The proposed graphene-based platform is flexible, comprising a programmable synaptic array which can be configured for different initial synaptic weights and plasticity functionalities and a spiking neuronal array, onto which various neural network structures can be mapped according to the application requirements and constraints. To demonstrate the validity of the synaptic weights training methodology and the suitability of the proposed SNN architecture for practical utilization, we consider character recognition and edge detection applications. In each case, the graphene-based platform is configured as per the application tailored SNN topology and initial state and SPICE simulated to evaluate its reaction to the applied input stimuli. For the first application, a 2-layer SNN is used to perform character recognition for 5 vowels. Our simulation indicates that the graphene-based SNN can achieve comparable recognition accuracy with the one delivered by a functionally equivalent Artificial Neural Network. Further, we reconfigure the architecture for a 3-layer SNN to perform edge detection on 2 grayscale images. SPICE simulation results indicate that the edge extraction results are close agreement with the one produced by classical edge detection operators. Our results suggest the feasibility and flexibility of the proposed approach for various application purposes. Moreover, the utilized graphene-based synapses and neurons operate at low supply voltage, consume low energy per spike, and exhibit small footprints, which are desired properties for largescale energy-efficient implementations.
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一种基于可重构石墨烯的峰值神经网络结构
在本文中,我们提出了一种可重构的基于石墨烯的峰值神经网络(SNN)架构和一种初始突触权值确定的训练方法。所提出的基于石墨烯的平台是灵活的,包括一个可编程的突触阵列,可以配置不同的初始突触权重和可塑性功能,以及一个峰值神经元阵列,可以根据应用需求和约束将各种神经网络结构映射到其上。为了证明突触权值训练方法的有效性以及所提出的SNN架构在实际应用中的适用性,我们考虑了字符识别和边缘检测的应用。在每种情况下,基于石墨烯的平台都根据应用定制的SNN拓扑和初始状态进行配置,并通过SPICE模拟来评估其对应用输入刺激的反应。对于第一个应用程序,使用两层SNN来执行5个元音的字符识别。我们的仿真表明,基于石墨烯的SNN可以达到与功能等效的人工神经网络相当的识别精度。此外,我们重新配置了3层SNN的架构,以对2幅灰度图像进行边缘检测。SPICE仿真结果表明,边缘提取的结果与经典边缘检测算子的结果吻合较好。我们的结果表明,所提出的方法的可行性和灵活性,为各种应用目的。此外,所利用的基于石墨烯的突触和神经元在低电源电压下工作,每个尖峰消耗低能量,并且具有小足迹,这些都是大规模节能实现所需的特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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