在深度卷积神经网络中编码时间信息

IF 1.5 Q3 ERGONOMICS
Frontiers in neuroergonomics Pub Date : 2024-06-19 eCollection Date: 2024-01-01 DOI:10.3389/fnrgo.2024.1287794
Avinash Kumar Singh, Luigi Bianchi
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引用次数: 0

摘要

深度学习技术的最新发展吸引了人们对脑电图(EEG)信号解码和分类的关注。尽管在利用脑电信号的不同特征方面做出了许多努力,但结合局部和全局特征使用随时间变化的特征仍是一项重大的研究挑战。为了捕捉时间依赖性信息,人们多次尝试重塑深度学习卷积神经网络(CNN)。这些特征通常是手工制作的特征,如功率比,或将数据分割成与特定属性相关的较小窗口,如 300 毫秒处的峰值。然而,这些方法虽然部分解决了问题,但同时也阻碍了 CNN 学习数据中可能存在的未知信息的能力。其他方法,如递归神经网络,非常适合在存在不相关的连续数据的情况下从脑电信号中学习与时间相关的信息。为了解决这个问题,我们提出了一种编码核(EnK),一种新颖的时间编码方法,它能在 CNN 的垂直卷积操作中独特地引入时间分解信息。除了局部和全局特征外,编码信息还能让 CNN 学习与时间相关的特征。我们在多个脑电图数据集上进行了广泛的实验--物理人机协作、P300 视觉诱发电位、运动图像、运动相关皮层电位以及使用生理信号进行情感分析的数据集。与基础模型相比,EnK 的平均平方误差 (MSE) 降低了 6.5%,F1 分数与所有数据集的平均值相比提高了 9.5%,表现优于现有技术。这些结果支持了我们的方法,并显示了提高生理和非生理数据性能的巨大潜力。此外,EnK 几乎可以应用于任何深度学习架构,只需极少的努力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Encoding temporal information in deep convolution neural network.

A recent development in deep learning techniques has attracted attention to the decoding and classification of electroencephalogram (EEG) signals. Despite several efforts to utilize different features in EEG signals, a significant research challenge is using time-dependent features in combination with local and global features. Several attempts have been made to remodel the deep learning convolution neural networks (CNNs) to capture time-dependency information. These features are usually either handcrafted features, such as power ratios, or splitting data into smaller-sized windows related to specific properties, such as a peak at 300 ms. However, these approaches partially solve the problem but simultaneously hinder CNNs' capability to learn from unknown information that might be present in the data. Other approaches, like recurrent neural networks, are very suitable for learning time-dependent information from EEG signals in the presence of unrelated sequential data. To solve this, we have proposed an encoding kernel (EnK), a novel time-encoding approach, which uniquely introduces time decomposition information during the vertical convolution operation in CNNs. The encoded information lets CNNs learn time-dependent features in addition to local and global features. We performed extensive experiments on several EEG data sets-physical human-robot collaborations, P300 visual-evoked potentials, motor imagery, movement-related cortical potentials, and the Dataset for Emotion Analysis Using Physiological Signals. The EnK outperforms the state of the art with an up to 6.5% reduction in mean squared error (MSE) and a 9.5% improvement in F1-scores compared to the average for all data sets together compared to base models. These results support our approach and show a high potential to improve the performance of physiological and non-physiological data. Moreover, the EnK can be applied to virtually any deep learning architecture with minimal effort.

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