Influence of Temporal and Frequency Selective Patterns Combined with CSP Layers on Performance in Exoskeleton-Assisted Motor Imagery Tasks

NeuroSci Pub Date : 2024-05-11 DOI:10.3390/neurosci5020012
C. D. Guerrero-Méndez, C. F. Blanco-Díaz, H. Rivera-Flor, Pedro Henrique Fabriz-Ulhoa, Eduardo Antonio Fragoso-Dias, Rafhael Milanezi de Andrade, D. Delisle-Rodríguez, T. F. Bastos-Filho
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Abstract

Common Spatial Pattern (CSP) has been recognized as a standard and powerful method for the identification of Electroencephalography (EEG)-based Motor Imagery (MI) tasks when implementing brain–computer interface (BCI) systems towards the motor rehabilitation of lost movements. The combination of BCI systems with robotic systems, such as upper limb exoskeletons, has proven to be a reliable tool for neuromotor rehabilitation. Therefore, in this study, the effects of temporal and frequency segmentation combined with layer increase for spatial filtering were evaluated, using three variations of the CSP method for the identification of passive movement vs. MI+passive movement. The passive movements were generated using a left upper-limb exoskeleton to assist flexion/extension tasks at two speeds (high—85 rpm and low—30 rpm). Ten healthy subjects were evaluated in two recording sessions using Linear Discriminant Analysis (LDA) as a classifier, and accuracy (ACC) and False Positive Rate (FPR) as metrics. The results allow concluding that the use of temporal, frequency or spatial selective information does not significantly (p< 0.05) improve task identification performance. Furthermore, dynamic temporal segmentation strategies may perform better than static segmentation tasks. The findings of this study are a starting point for the exploration of complex MI tasks and their application to neurorehabilitation, as well as the study of brain effects during exoskeleton-assisted MI tasks.
结合 CSP 层的时间和频率选择性模式对外骨骼辅助运动想象任务表现的影响
通用空间模式(CSP)已被公认为是一种标准而强大的方法,可用于在实施脑机接口(BCI)系统时识别基于脑电图(EEG)的运动想象(MI)任务,从而实现失能运动康复。事实证明,BCI 系统与机器人系统(如上肢外骨骼)的结合是神经运动康复的可靠工具。因此,在本研究中,使用 CSP 方法的三种变体来识别被动运动与 MI+ 被动运动,评估了时间和频率分割与空间过滤层增加相结合的效果。被动运动是使用左上肢外骨骼以两种速度(高 85 rpm 和低 30 rpm)辅助屈伸任务产生的。以线性判别分析(LDA)为分类器,以准确率(ACC)和误判率(FPR)为指标,对 10 名健康受试者进行了两次记录评估。结果表明,使用时间、频率或空间选择性信息并不能显著提高任务识别性能(P< 0.05)。此外,动态时间分割策略可能比静态分割任务表现更好。这项研究的结果是探索复杂的多元智能任务及其在神经康复中的应用,以及研究外骨骼辅助多元智能任务期间大脑效应的一个起点。
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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