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基于改进 StackCNN 网络和集成学习的脑电信号视觉分类算法()

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《郑州大学学报(工学版)》[ISSN:1671-6833/CN:41-1339/T]

卷:: 45
期数:: 2024年05期

页码:: 69-76

栏目:

出版日期:: 2024-08-08

文章信息/Info

Title:: EEG Visual Classification Algorithm Based on Improved StackCNN Network andEnsemble Learning

文章编号:: 1671-6833(2024)05-0069-08

作者:: 杨青¹; 2; 3; 王亚群¹; 2; 3; 文斗¹; 2; 3; 王莹¹; 2; 3; 王翔宇¹; 2; 3; 1. 华中师范大学人工智能与智慧学习湖北省重点实验室,湖北武汉 430079;2. 华中师范大学计算机学院,湖北武汉 430079;3. 华中师范大学国家语言资源监测与研究网络媒体中心,湖北武汉 430079

Author(s):: YANG Qing¹; 2; 3; WANG Yaqun¹; 2; 3; WEN Dou¹; 2; 3; WANG Ying¹; 2; 3; WANG Xiangyu¹; 2; 3; 1. Hubei Provincial Key Laboratory of Artificial Intelligence and Smart Learning,Central China Normal University, Wuhan 430079,China; 2. School of Computer,Central China Normal University, Wuhan 430079,China; 3. National Language Resources Monitoring &Research Center for Network Media,Central China Normal University, Wuhan 430079,China

关键词:: 脑电图; 视觉分类; 卷积神经网络; Bagging 算法; ResNet 网络

Keywords:: electroencephagram; vision classification; convolutional neural network; Bagging algorithm; ResNet network

分类号:: TP399

DOI:: 10.13705/j.issn.1671-6833.2024.02.009

文献标志码:: A

摘要:: 针对直接使用图像诱发的脑电信号进行视觉分类的现有研究少,并且视觉分类的平均准确率低等问题,设计了一种卷积神经网络( CNN) 和集成学习相结合的方法,用于学习脑电信号相关的视觉特征表示。通过在StackCNN 网络中加入 K-max 池化方法,解决在提取脑电特征时信息丢失的问题,并结合 Bagging 算法增强网络的泛化能力,该方法称为 StackCNN-B。采用基于残差神经网络(ResNet)回归对图像进行分类,验证 StackCNN-B 方法在图像分类上的性能。消融实验及与现有研究对比实验的结果表明:所提方法识别准确率较高,在学习脑电信号的视觉特征表示上的平均准确率达到 99. 78%,在图像分类上的平均准确率达到 96. 45%,与 Bi-LSTM-AttGW 方法相比,平均提高了 0. 28 百分点和 2. 97 百分点。研究结果验证了脑电信号可以有效地解码与视觉识别相关的人类大脑活动,也表明所提出 StackCNN-B 模型的优越性。

Abstract:: Abstract: Aiming at the limited studies researches on visual classification directly using image-induced EEG signals and low average accuracy of visual classification, a method combining convolutional neural networks ( CNN)and ensemble learning was designed to learn the visual feature representation related to EEG signals. By adding theK-max pooling method to the stackCNN network to solve the problem of information loss when extracting EEGfeatures, and combining with Bagging algorithm to enhance the generalization ability of the network, this methodwas called StackCNN-B. In order to verify the performance of StackCNN-B method in image classification, imageswere classified using deep residual network regression. The results of ablation experiments and comparativeexperiments with existing studies showed that the recognition accuracy of this method was high. The averageaccuracy in learning the visual feature representation of EEG signals was 99. 78%, and the average accuracy inimage classification was 96. 45%. Compared with the most advanced Bi-LSTM-AttGW method, the averageaccuracy was improved by 0. 28 percentage point and 2. 97 percentage point. The results verified that EEG signalscould effectively decode human brain activities related to visual recognition, proved the advantages of the proposedStackCNN-B model.

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更新日期/Last Update: 2024-09-02

《郑州大学学报(工学版)》[ISSN:1671-6833/CN:41-1339/T]

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