Yi Zhong, Zilin Wang, Xiaoxin Cui, Jian Cao, Yuan Wang
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引用次数: 0
摘要
脉冲神经网络是在芯片上实现类脑智能的一个很有前途的尝试。它的学习规则,即spike- time -dependent plasticity (STDP),来源于神经生物学,被认为是促进低成本和高性能无监督训练的有力候选。在本文中,我们提出了一种基于时序编码的STDP学习方法(TC-STDP)来验证基于计数器和查找表的电路设计在神经形态原型芯片上。为了以无监督的方式进行片上STDP学习,本文更侧重于详细介绍实验程序和实际评估,其中我们引入匹配分数作为定量指标来进行标签分配和准确性确认。评估实验表明,无监督STDP学习在MNIST和EMNIST数据集上的片上识别准确率分别为93.51%和80.33%。此外,在ModelNet40 3D数据集上进行的实验也验证了无监督STDP规则在执行可能的增量学习方面的有效性。
Unsupervised Learning of Spike-Timing-Dependent Plasticity Based on a Neuromorphic Implementation
Spiking neural network is a promising endeavor to fulfill brain-like intelligence on the chip. Its learning rule, i.e., spike-timing-dependent plasticity (STDP), derived from neurobiology, is perceived as a powerful candidate to facilitate low-cost and high-performance unsupervised training. In this paper, we present a temporal coding based STDP learning method (TC-STDP) to verify the counter and look-up table based circuit design on a neuromorphic prototype chip. In order to perform on-chip STDP learning in an unsupervised manner, this paper concentrates more on detailing the experimental procedures and practical evaluations, where we introduce the matching score as a quantitative index to carry out label assignment and accuracy confirmation. Evaluation experiments demonstrate that the unsupervised STDP learning achieves best on-chip recognition accuracies of 93.51%, 80.33% on MNIST and EMNIST datasets, respectively. Moreover, experiments conducted on ModelNet40 3D dataset also validate the effectiveness of unsupervised STDP rule to perform possible incremental learning.
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