基于加速度计信号的偏瘫检测方法

计算机工程与设计 Pub Date : 2021-09-24 DOI:10.1109/SEEDA-CECNSM53056.2021.9566216

Vasileios Christou, Alexandros Bantaloukas-Arjmand, D. Dimopoulos, D. Varvarousis, A. Tzallas, Ch Gogos, M. Tsipouras, A. Ploumis, N. Giannakeas

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引用次数: 1

摘要

本文介绍了一种能够在健康和非健康受试者之间自动分类偏瘫类型(右侧或左侧身体瘫痪)的方法。该方法利用了RehaGait移动步态分析系统加速度计传感器的数据。这些数据经过预处理和特征提取阶段，然后作为输入发送到缩放共轭梯度反向传播(SCG-BP)训练的神经网络。该系统使用一个定制的数据集进行测试，该数据集包含10名健康患者和20名偏瘫患者(右偏瘫或左偏瘫)。系统的实验部分使用了7个传感器，分别放置在每个受试者的左右脚、左右小腿、左右大腿和臀部。每个传感器捕获3种不同设备类型的三维(3D)信号:加速度计，磁力计和陀螺仪。该系统仅利用加速度计数据并将其分割为2秒窗口，分类准确率达到87.71%。

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Neural Network-Based approach for Hemiplegia Detection via Accelerometer Signals

This article introduces a method that can automatically classify the hemiplegia type (right or left side of the body is paralyzed) between healthy and non-healthy subjects. The proposed method utilizes the data taken from the accelerometer sensor of the RehaGait mobile gait analysis system. These data undergo a pre-processing and feature extraction stage before being sent as input to a scaled conjugate gradient backpropagation (SCG-BP) trained neural network. The proposed system is tested using a custom-created dataset containing 10 healthy and 20 patients suffering from hemiplegia (right or left). The experimental part of the system utilized 7 sensors placed on the left and right foot, the left and right shank, the left and right thigh, and the hip of each subject. Each sensor captured a 3-dimensional (3D) signal from 3 different device types: accelerometer, magnetometer, and gyroscope. The system utilized and split into 2-second windows only the accelerometer data, achieving a classification accuracy of 87.71%.

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来源期刊

计算机工程与设计

自引率

0.00%

发文量

20353

期刊介绍： Computer Engineering and Design is supervised by China Aerospace Science and Industry Corporation and sponsored by the 706th Institute of the Second Academy of China Aerospace Science and Industry Corporation. It was founded in 1980. The purpose of the journal is to disseminate new technologies and promote academic exchanges. Since its inception, it has adhered to the principle of combining depth and breadth, theory and application, and focused on reporting cutting-edge and hot computer technologies. The journal accepts academic papers with innovative and independent academic insights, including papers on fund projects, award-winning research papers, outstanding papers at academic conferences, doctoral and master's theses, etc.