量化脑电信号的分数动态稳定性作为认知运动控制的生物标记

Frontiers in control engineering Pub Date : 2022-02-01 DOI:10.3389/fcteg.2021.787747

Emily A. Reed, Paul C Bogdan, S. Pequito

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引用次数: 2

摘要

评估生物系统模型的稳定性有助于揭示遗传学、神经科学和医学领域的大量新见解。在本文中，我们重点分析神经信号的稳定性，包括脑电图（EEG）信号。有趣的是，时空离散时间线性分数阶系统（DTLFOS）已被证明能够准确有效地表示各种神经和生理信号。在这里，我们利用DTLFOS的稳定性条件来评估真实世界的EEG数据集。通过分析运动和休息任务期间脑电图信号的稳定性，我们提供了稳定性量化作为认知运动控制的生物标志物的有用性的证据。

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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Quantification of Fractional Dynamical Stability of EEG Signals as a Bio-Marker for Cognitive Motor Control

Assessing the stability of biological system models has aided in uncovering a plethora of new insights in genetics, neuroscience, and medicine. In this paper, we focus on analyzing the stability of neurological signals, including electroencephalogram (EEG) signals. Interestingly, spatiotemporal discrete-time linear fractional-order systems (DTLFOS) have been shown to accurately and efficiently represent a variety of neurological and physiological signals. Here, we leverage the conditions for stability of DTLFOS to assess a real-world EEG data set. By analyzing the stability of EEG signals during movement and rest tasks, we provide evidence of the usefulness of the quantification of stability as a bio-marker for cognitive motor control.

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Frontiers in control engineering

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