Research on Lower Limb Motion Recognition Based on Fusion of sEMG and Accelerometer Signals

Research on Lower Limb Motion Recognition Based on Fusion of sEMG and Accelerometer Signals

Since surface electromyograghic (sEMG) signals are non-invasive and capable of reflecting humans’ motion intention, they have been widely used for the motion recognition of upper limbs. However, limited research has been conducted for lower limbs, because the sEMGs of lower limbs are easily affected...

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Bibliographic Details
Published in:Symmetry (Basel) Vol. 9; no. 8; p. 147
Main Authors: Ai, Qingsong, Zhang, Yanan, Qi, Weili, Liu, Quan, Chen, and Kun
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-08-2017
Subjects:
accelerometer signals
Accelerometers
Classification
Correlation coefficients
Curve fitting
Discriminant analysis
Feature extraction
feature fusion
Feature recognition
Filtration
Gravitation
Limbs
Motion perception
motion recognition
Spectral correlation
Support vector machines
surface electromyograghic (sEMG)
Vibration
Wavelet analysis
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Summary:Since surface electromyograghic (sEMG) signals are non-invasive and capable of reflecting humans’ motion intention, they have been widely used for the motion recognition of upper limbs. However, limited research has been conducted for lower limbs, because the sEMGs of lower limbs are easily affected by body gravity and muscle jitter. In this paper, sEMG signals and accelerometer signals are acquired and fused to recognize the motion patterns of lower limbs. A curve fitting method based on median filtering is proposed to remove accelerometer noise. As for movement onset detection, an sEMG power spectral correlation coefficient method is used to detect the start and end points of active signals. Then, the time-domain features and wavelet coefficients of sEMG signals are extracted, and a dynamic time warping (DTW) distance is used for feature extraction of acceleration signals. At last, five lower limbs’ motions are classified and recognized by using Gaussian kernel-based linear discriminant analysis (LDA) and support vector machine (SVM) respectively. The results prove that the fused feature-based classification outperforms the classification with only sEMG signals or accelerometer signals, and the fused feature can achieve 95% or higher recognition accuracy, demonstrating the validity of the proposed method.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym9080147