多层尖峰神经网络的分数阶尖峰计时梯度下降法

IF 5.5 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Yi Yang, Richard M. Voyles, Haiyan H. Zhang, Robert A. Nawrocki
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引用次数: 0

摘要

随着对人类大脑神经元活动的深入了解,受生物启发的尖峰神经网络(SNN)受到了更多关注。与非尖峰深度神经网络(DNN)相比,SNN 利用生物现实的低功耗事件驱动神经形态架构,能更有效地编码和传输时空信息。然而,由于连接的尖峰神经元的尖峰计时可塑性(STDP)在现有的反向传播学习方案中很难实现和解释,SNN 的监督学习仍然是一个挑战。本文提出了一种分数阶尖峰计时依赖梯度下降(FO-STDGD)学习模型,该模型考虑了一个导出的非线性激活函数,该函数描述了非泄漏整合发射神经元的准瞬时发射率与时间膜电位之间的关系。由于 FO-STDGD 将分数梯度下降法纳入了尖峰计时损失梯度的计算,因此该训练策略可以推广到 0 到 2 之间的任何分数阶。我们在 MNIST 和 DVS128 手势数据集上测试了所提出的 FO-STDGD 模型,并分析了其在不同网络结构和分数阶数下的准确性。结果发现,分类准确率随着分数阶数的增加而提高,具体来说,分数阶数为 1.9 的情况比分数阶数为 1 的情况(传统梯度下降)提高了 155%。此外,在相同的 SNN 结构和训练历时条件下,我们的方案也展示了最先进的计算效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fractional-order spike-timing-dependent gradient descent for multi-layer spiking neural networks
Accumulated detailed knowledge about the neuronal activities in human brains has brought more attention to bio-inspired spiking neural networks (SNNs). In contrast to non-spiking deep neural networks (DNNs), SNNs can encode and transmit spatiotemporal information more efficiently by exploiting biologically realistic and low-power event-driven neuromorphic architectures. However, the supervised learning of SNNs still remains a challenge because the spike-timing-dependent plasticity (STDP) of connected spiking neurons is difficult to implement and interpret in existing backpropagation learning schemes. This paper proposes a fractional-order spike-timing-dependent gradient descent (FO-STDGD) learning model by considering a derived nonlinear activation function that describes the relationship between the quasi-instantaneous firing rate and the temporal membrane potentials of nonleaky integrate-and-fire neurons. The training strategy can be generalized to any fractional orders between 0 and 2 since the FO-STDGD incorporates the fractional gradient descent method into the calculation of spike-timing-dependent loss gradients. The proposed FO-STDGD model is tested on the MNIST and DVS128 Gesture datasets and its accuracy under different network structure and fractional orders is analyzed. It can be found that the classification accuracy increases as the fractional order increases, and specifically, the case of fractional order 1.9 improves by 155 % relative to the case of fractional order 1 (traditional gradient descent). In addition, our scheme demonstrates the state-of-the-art computational efficacy for the same SNN structure and training epochs.
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来源期刊
Neurocomputing
Neurocomputing 工程技术-计算机:人工智能
CiteScore
13.10
自引率
10.00%
发文量
1382
审稿时长
70 days
期刊介绍: Neurocomputing publishes articles describing recent fundamental contributions in the field of neurocomputing. Neurocomputing theory, practice and applications are the essential topics being covered.
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