Pattern recognition of surface electromyography signal based on wavelet coefficient entropy
Xiao Hu, Ying Gao, Wai-Xi Liu
DOI: 10.4236/health.2009.12020   PDF    HTML     5,714 Downloads   11,156 Views   Citations


This paper introduced a novel, simple and ef-fective method to extract the general feature of two surface EMG (electromyography) signal patterns: forearm supination (FS) surface EMG signal and forearm pronation (FP) surface EMG signal. After surface EMG (SEMG) signal was decomposed to the fourth resolution level with wavelet packet transform (WPT), its whole scaling space (with frequencies in the interval (0Hz, 500Hz]) was divided into16 frequency bands (FB). Then wavelet coefficient entropy (WCE) of every FB was calculated and corre-spondingly marked with WCE(n) (from the nth FB, n=1,2,…16). Lastly, some WCE(n) were chosen to form WCE feature vector, which was used to distinguish FS surface EMG signals from FP surface EMG signals. The result showed that the WCE feather vector consisted of WCE(7) (187.25Hz, 218.75Hz) and WCE(8) (218.75Hz, 250Hz) can more effectively recog-nize FS and FP patterns than other WCE feature vector or the WPT feature vector which was gained by the combination of WPT and principal components analysis.

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Hu, X. , Gao, Y. and Liu, W. (2009) Pattern recognition of surface electromyography signal based on wavelet coefficient entropy. Health, 1, 121-126. doi: 10.4236/health.2009.12020.

Conflicts of Interest

The authors declare no conflicts of interest.


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