An Emotion Recognition Embedded System using a Lightweight Deep Learning Model.

IF 1.3 Q4 ENGINEERING, BIOMEDICAL Journal of Medical Signals & Sensors Pub Date : 2023-08-31 eCollection Date: 2023-10-01 DOI:10.4103/jmss.jmss_59_22

Mehdi Bazargani, Amir Tahmasebi, Mohammadreza Yazdchi, Zahra Baharlouei

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Abstract

Background: Diagnosing emotional states would improve human-computer interaction (HCI) systems to be more effective in practice. Correlations between Electroencephalography (EEG) signals and emotions have been shown in various research; therefore, EEG signal-based methods are the most accurate and informative.

Methods: In this study, three Convolutional Neural Network (CNN) models, EEGNet, ShallowConvNet and DeepConvNet, which are appropriate for processing EEG signals, are applied to diagnose emotions. We use baseline removal preprocessing to improve classification accuracy. Each network is assessed in two setting ways: subject-dependent and subject-independent. We improve the selected CNN model to be lightweight and implementable on a Raspberry Pi processor. The emotional states are recognized for every three-second epoch of received signals on the embedded system, which can be applied in real-time usage in practice.

Results: Average classification accuracies of 99.10% in the valence and 99.20% in the arousal for subject-dependent and 90.76% in the valence and 90.94% in the arousal for subject independent were achieved on the well-known DEAP dataset.

Conclusion: Comparison of the results with the related works shows that a highly accurate and implementable model has been achieved for practice.

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一个使用轻量级深度学习模型的情感识别嵌入式系统。

背景：诊断情绪状态将改善人机交互系统，使其在实践中更加有效。脑电图（EEG）信号与情绪之间的相关性已在各种研究中得到证实；因此，基于脑电信号的方法是最准确、信息量最大的方法。方法：采用EEGNet、ShallowConvNet和DeepConvNet三种适合于脑电信号处理的卷积神经网络（CNN）模型对情绪进行诊断。我们使用基线去除预处理来提高分类精度。每个网络都以两种设置方式进行评估：受试者依赖和受试者独立。我们改进了选定的CNN模型，使其重量轻，可在树莓派处理器上实现。在嵌入式系统上，每三秒接收一次信号，就会识别出情绪状态，这可以在实践中实时应用。结果：在著名的DEAP数据集上，受试者依赖性的平均分类准确率为99.10%，唤醒的平均分类正确率为99.20%，而受试者独立性的平均归类准确率为90.76%，唤醒的准确率为90.04%。结论：将结果与相关工作进行比较表明，该模型具有高度的准确性和可实施性。

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

Journal of Medical Signals & Sensors ENGINEERING, BIOMEDICAL-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

33 weeks

期刊介绍： JMSS is an interdisciplinary journal that incorporates all aspects of the biomedical engineering including bioelectrics, bioinformatics, medical physics, health technology assessment, etc. Subject areas covered by the journal include: - Bioelectric: Bioinstruments Biosensors Modeling Biomedical signal processing Medical image analysis and processing Medical imaging devices Control of biological systems Neuromuscular systems Cognitive sciences Telemedicine Robotic Medical ultrasonography Bioelectromagnetics Electrophysiology Cell tracking - Bioinformatics and medical informatics: Analysis of biological data Data mining Stochastic modeling Computational genomics Artificial intelligence & fuzzy Applications Medical softwares Bioalgorithms Electronic health - Biophysics and medical physics: Computed tomography Radiation therapy Laser therapy - Education in biomedical engineering - Health technology assessment - Standard in biomedical engineering.