Adaptive Filtering of Accelerometer and Electromyography Signals Using Extended Kalman Filter for Chewing Muscle Activities

IF 0.5 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Advances in Electrical and Electronic Engineering Pub Date : 2022-10-03 DOI:10.15598/aeee.v20i3.4437

T. Sonmezocak, Serkan Kurt

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Abstract

. Today Electromyography (EMG) and accelerometer (MEMS) based signals can be used in the clinical diagnosis of physical states of muscle activities such as fatigue, muscle weakness, pain, and tremors and in external or wearable robotic exoskeletal systems used in rehabilitation areas. During the record-ing of these signals taken from the skin surface through non-invasive processes, analysis of the signal becomes difficult due to the electrodes attached to the skin not fully contacting, involuntary body movements, and noises from peripheral muscles. In addition, parameters such as age and skin structure of the subjects can also affect the signal. Considering these nega-tive factors, a new adaptive method based on Extended Kalman Filtering (EKF) model for more effective filtering of the muscle signals based on both EMG and MEMS is proposed in this study. Moreover, the accuracy of the parametric values determined by the filter automatically according to the most effective time and frequency features that represent noisy and filtered signals was determined by different machine learning and classification algorithms. It was verified that the filter performs adaptive filtering with 100 % effectiveness with Linear Discriminant.

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用扩展卡尔曼滤波器对咀嚼肌活动的加速度计和肌电图信号进行自适应滤波

．如今，基于肌电图(EMG)和加速度计(MEMS)的信号可用于临床诊断肌肉活动的物理状态，如疲劳、肌肉无力、疼痛和震颤，以及用于康复领域的外部或可穿戴机器人外骨骼系统。在记录这些通过非侵入性过程从皮肤表面获取的信号时，由于附着在皮肤上的电极没有完全接触，不自主的身体运动和周围肌肉的噪音，信号的分析变得困难。此外，受试者的年龄、皮肤结构等参数也会影响信号。考虑到这些不利因素，本研究提出了一种基于扩展卡尔曼滤波(EKF)模型的自适应方法，以更有效地滤波基于肌电和MEMS的肌肉信号。此外，滤波器根据代表噪声和滤波信号的最有效的时间和频率特征自动确定的参数值的准确性由不同的机器学习和分类算法确定。实验结果表明，该滤波器具有100%的线性判别自适应滤波效果。

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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