基于生物识别(BCI)的康复:感官运动皮层节奏系统化的创新性增强。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Anna Latha M., Ramesh R.
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引用次数: 0

摘要

该研究提出了一种新颖的脑电图(EEG)分类策略,用于实时脑机接口的康复应用。该方法利用五种交叉共同空间模式(FCCSP)来开发一种运动/图像系统化模型,该模型可提取多域特征并具有出色的性能。其目标是消除脑电图非稳态性所造成的影响。文章重点介绍了一种实时技术的研究成果,该技术被纳入了一个综合预测系统,并提供了一种创新方法来提高实时感觉-运动皮层节奏(SMR)的准确性。预处理后,准确率从使用原始脑电图的 57.14% 提高到 85.71%,公共领域 SMR 的准确率从 58.08% 提高到 97.94%。利用 FCCSP 对提议的巴特沃斯带通滤波器进行了优化,以确定理想的带宽,从而将整个脑电图特征纳入贝塔波。然后,将相关特征移除分类器混合系统化与 FCCSP 方法相结合,创建改进的预测模型。因此,在应用于实时数据集和 PhysioNet 数据集时,结果系统分别取得了 85.71% 和 97.94% 的出色准确率。这证明了该策略在提高 SMR 预测效率方面的稳健性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rehabilitation Based on BCI: An Innovative Enhancement for Sensorimotor Cortex Rhythms Systemization

The research proposes a novel strategy for categorizing electroencephalograms (EEG) in real-time brain-computer interfaces that have rehabilitation applications. The methodology utilizes Five Cross-Common Spatial Patterns (FCCSP) to develop a motor movement/imagery systemization model that extracts multi-domain characteristics with excellent performance. The goal is to eliminate the impact caused by EEG's nonstationarity. The article highlights the findings of a real-time technique that is incorporated into a comprehensive prediction system, and it offers an innovative method to boost accuracy in real-time Sensory-Motor cortex Rhythms (SMR). The accuracy increased from 57.14% using raw EEG to 85.71% after preprocessing, and from 58.08% to 97.94% in public domain SMR. The proposed Butterworth bandpass filter is optimized using the FCCSP to determine the ideal bandwidth that incorporates the whole EEG features in beta waves. The Hybrid Systemization of the Correlated Feature Removal classifier is then integrated with the FCCSP method to create improved predictive models. As a consequence, while applied to real-time and PhysioNet datasets, the outcome system achieved outstanding accuracy values of 85.71% and 97.94%, respectively. This demonstrates the robustness of the strategy to increase SMR prediction efficiency.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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