基于脑电信号的长短期记忆(LSTM)模型在应力检测中的实现

Ayushi Jain
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引用次数: 0

摘要

压力是现代社会的普遍问题,如果不加以解决,可能会导致各种健康问题。因此,准确的压力检测对于提供有效的干预措施和改善整体健康状况至关重要。本研究提出了一个长短期记忆(LSTM)模型的实现,利用脑电图(EEG)信号来检测压力。研究人员收集了一组参与者在接受压力诱导任务和控制任务时的脑电图信号。使用滤波和伪影去除技术对数据进行预处理,以确保高质量和可靠性。然后利用预处理后的脑电信号提取相关特征,如频谱功率和相干性,作为LSTM模型的输入。开发了一个深度学习架构,结合LSTM层和其他组件来优化模型的性能。使用可用的数据集对LSTM模型进行训练和验证。结果表明,LSTM模型在准确性、灵敏度和特异性方面明显优于其他算法。此外,该模型在检测不同任务和脑电通道的应力方面具有鲁棒性。这些发现表明,基于lstm的模型有可能被用作现实生活场景中压力检测的有效工具,并有助于开发更个性化的压力管理干预措施。未来的研究应侧重于完善模型,并探索其在不同人群和环境中的适用性。
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Implementation of Long Short-Term Memory (LSTM) Model for Stress Detection Using EEG Signal
Stress is a common issue in modern society and can lead to various health problems when left unaddressed. Accurate stress detection is, therefore, crucial in order to provide effective interventions and improve overall well-being. This study presents the implementation of a Long Short-Term Memory (LSTM) model to detect stress using electroencephalogram (EEG) signals. EEG signals were collected from a sample of participants while they were exposed to stress-inducing tasks and control tasks. The data was pre-processed using filtering and artifact removal techniques to ensure high quality and reliability. The pre-processed EEG signals were then used to extract relevant features, such as spectral power and coherence, which served as inputs to the LSTM model. A deep learning architecture was developed, incorporating the LSTM layers and other components to optimize the model's performance. The LSTM model was trained and validated using the available dataset. The results showed that the LSTM model significantly outperformed the other algorithms in terms of accuracy, sensitivity, and specificity. Furthermore, the model demonstrated robustness in detecting stress across various tasks and EEG channels. These findings suggest that LSTM-based models have the potential to be used as effective tools for stress detection in real-life scenarios, and can contribute to the development of more personalized stress management interventions. Future research should focus on refining the model and exploring its applicability in different populations and settings.
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Information Technology in Industry
Information Technology in Industry COMPUTER SCIENCE, SOFTWARE ENGINEERING-
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