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非加性熵在去趋势化力传感器数据中的应用,以指示前庭系统功能障碍患者的平衡紊乱。

Nonadditive Entropy Application to Detrended Force Sensor Data to Indicate Balance Disorder of Patients with Vestibular System Dysfunction.

作者信息

Köse Harun Yaşar, İkizoğlu Serhat

机构信息

Department of Mechatronics Engineering, Faculty of Electric and Electronics, Istanbul Technical University (ITU), 34469 Istanbul, Türkiye.

Department of Control and Automation Engineering, Faculty of Electric and Electronics, Istanbul Technical University (ITU), 34469 Istanbul, Türkiye.

出版信息

Entropy (Basel). 2023 Sep 27;25(10):1385. doi: 10.3390/e25101385.

DOI:10.3390/e25101385
PMID:37895507
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10606935/
Abstract

The healthy function of the vestibular system (VS) is of vital importance for individuals to carry out their daily activities independently and safely. This study carries out Tsallis entropy (TE)-based analysis on insole force sensor data in order to extract features to differentiate between healthy and VS-diseased individuals. Using a specifically developed algorithm, we detrend the acquired data to examine the fluctuation around the trend curve in order to consider the individual's walking habit and thus increase the accuracy in diagnosis. It is observed that the TE value increases for diseased people as an indicator of the problem of maintaining balance. As one of the main contributions of this study, in contrast to studies in the literature that focus on gait dynamics requiring extensive walking time, we directly process the instantaneous pressure values, enabling a significant reduction in the data acquisition period. The extracted feature set is then inputted into fundamental classification algorithms, with support vector machine (SVM) demonstrating the highest performance, achieving an average accuracy of 95%. This study constitutes a significant step in a larger project aiming to identify the specific VS disease together with its stage. The performance achieved in this study provides a strong motivation to further explore this topic.

摘要

前庭系统(VS)的健康功能对于个体独立且安全地开展日常活动至关重要。本研究对鞋垫力传感器数据进行基于Tsallis熵(TE)的分析,以提取特征来区分健康个体和患有VS疾病的个体。使用专门开发的算法,我们对采集到的数据进行去趋势处理,以检查趋势曲线周围的波动情况,从而考虑个体的行走习惯,进而提高诊断的准确性。可以观察到,患病个体的TE值会增加,这是维持平衡出现问题的一个指标。作为本研究的主要贡献之一,与文献中专注于需要大量行走时间的步态动力学的研究不同,我们直接处理瞬时压力值,从而显著缩短了数据采集周期。然后将提取的特征集输入到基本分类算法中,支持向量机(SVM)表现出最高的性能,平均准确率达到95%。本研究是一个更大项目中的重要一步,该项目旨在识别特定的VS疾病及其阶段。本研究取得的成果为进一步探索这一主题提供了强大的动力。

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