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关于星形胶质细胞在基于STDP的无监督脉冲神经网络中的自我修复作用

On the Self-Repair Role of Astrocytes in STDP Enabled Unsupervised SNNs.

作者信息

Rastogi Mehul, Lu Sen, Islam Nafiul, Sengupta Abhronil

机构信息

School of Electrical Engineering and Computer Science, Pennsylvania State University (PSU), University Park, PA, United States.

Department of Computer Science and Information Systems, Birla Institute of Technology and Science Pilani, Goa Campus, India.

出版信息

Front Neurosci. 2021 Jan 14;14:603796. doi: 10.3389/fnins.2020.603796. eCollection 2020.

DOI:10.3389/fnins.2020.603796
PMID:33519358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7841294/
Abstract

Neuromorphic computing is emerging to be a disruptive computational paradigm that attempts to emulate various facets of the underlying structure and functionalities of the brain in the algorithm and hardware design of next-generation machine learning platforms. This work goes beyond the focus of current neuromorphic computing architectures on computational models for neuron and synapse to examine other computational units of the biological brain that might contribute to cognition and especially self-repair. We draw inspiration and insights from computational neuroscience regarding functionalities of glial cells and explore their role in the fault-tolerant capacity of Spiking Neural Networks (SNNs) trained in an unsupervised fashion using Spike-Timing Dependent Plasticity (STDP). We characterize the degree of self-repair that can be enabled in such networks with varying degree of faults ranging from 50 to 90% and evaluate our proposal on the MNIST and Fashion-MNIST datasets.

摘要

神经形态计算正在成为一种具有颠覆性的计算范式,它试图在下一代机器学习平台的算法和硬件设计中模拟大脑底层结构和功能的各个方面。这项工作超越了当前神经形态计算架构对神经元和突触计算模型的关注,转而研究生物大脑中可能有助于认知尤其是自我修复的其他计算单元。我们从计算神经科学中汲取关于胶质细胞功能的灵感和见解,并探讨它们在使用基于脉冲时间依赖可塑性(STDP)进行无监督训练的脉冲神经网络(SNN)的容错能力中的作用。我们刻画了在故障程度从50%到90%不等的此类网络中能够实现的自我修复程度,并在MNIST和Fashion-MNIST数据集上评估了我们的方案。

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