Gated parametric neuron for spike-based audio recognition

IF 5.5 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
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引用次数: 0

Abstract

Spiking neural networks (SNNs) aim to simulate real neural networks in the human brain with biologically plausible neurons. The leaky integrate-and-fire (LIF) neuron is one of the most widely studied SNN architectures. However, it has the vanishing gradient problem when trained with backpropagation. Additionally, its neuronal parameters are often manually specified and fixed, in contrast to the heterogeneity of real neurons in the human brain. This paper proposes a gated parametric neuron (GPN) to process spatio-temporal information effectively with the gating mechanism. Compared with the LIF neuron, the GPN has two distinguishing advantages: (1) it copes well with the vanishing gradients by improving the flow of gradient propagation; and, (2) it learns spatio-temporal heterogeneous neuronal parameters automatically. Additionally, we use the same gate structure to eliminate initial neuronal parameter selection and design a hybrid recurrent neural network-SNN structure. Experiments on two spike-based audio datasets demonstrated that the GPN network outperformed several state-of-the-art SNNs, could mitigate vanishing gradients, and had spatio-temporal heterogeneous parameters. Our work shows the ability of SNNs to handle long-term dependencies and achieve high performance simultaneously.

用于基于尖峰的音频识别的门控参数神经元
尖峰神经网络(SNN)旨在用生物学上可信的神经元模拟人脑中的真实神经网络。泄漏整合-发射(LIF)神经元是研究最广泛的 SNN 架构之一。然而,在使用反向传播训练时,它存在梯度消失问题。此外,它的神经元参数通常是手动指定和固定的,这与人脑中真实神经元的异质性形成了鲜明对比。本文提出了一种门控参数神经元(GPN),利用门控机制有效处理时空信息。与 LIF 神经元相比,GPN 有两个显著的优点:(1)通过改善梯度传播的流量,它能很好地应对消失的梯度;(2)它能自动学习时空异构神经元参数。此外,我们使用相同的门结构来消除初始神经元参数选择,并设计了一种混合递归神经网络-SNN 结构。在两个基于尖峰的音频数据集上进行的实验表明,GPN 网络的性能优于几种最先进的 SNN,可以缓解梯度消失,并具有时空异构参数。我们的工作表明,SNN 有能力同时处理长期依赖性和实现高性能。
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
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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