Abstract
Due to the increment in hand motion types, electromyography (EMG) features are increasingly required for accurate EMG signals classification. However, increasing in the number of EMG features not only degrades classification performance, but also increases the complexity of the classifier. Feature selection is an effective process for eliminating redundant and irrelevant features. In this paper, we propose a new personal best (Pbest) guide binary particle swarm optimization (PBPSO) to solve the feature selection problem for EMG signal classification. First, the discrete wavelet transform (DWT) decomposes the signal into multiresolution coefficients. The features are then extracted from each coefficient to form the feature vector. After which pbest-guide binary particle swarm optimization (PBPSO) is used to evaluate the most informative features from the original feature set. In order to measure the effectiveness of PBPSO, binary particle swarm optimization (BPSO), genetic algorithm (GA), modified binary tree growth algorithm (MBTGA), and binary differential evolution (BDE) were used for performance comparison. Our experimental results show the superiority of PBPSO over other methods, especially in feature reduction; where it can reduce more than 90% of features while keeping a very high classification accuracy. Hence, PBPSO is more appropriate for application in clinical and rehabilitation applications.
Highlights
Electromyography (EMG) has received attention from biomedical researchers due to its potential in EMG pattern recognition
It is observed that modified binary tree growth algorithm (MBTGA) can provide satisfactory classification results in EMG
It is interesting to know whether MBTGA can achieve promising performance using the amputee dataset
Summary
Electromyography (EMG) has received attention from biomedical researchers due to its potential in EMG pattern recognition. Surface EMG is a non-invasive method that records the bioelectric signal generated by muscle activation. Current technologies have allowed the use of EMG pattern recognition to a broad range of applications such as man–machine interface, robot assisted rehabilitation device, and myoelectric prosthetic [1]. EMG signals are non-linear and non-stationary due to their complex nature. EMG signals are interrupted by noise and motion artifact [2]. Due to an increment in motion types, training and control strategies are becoming difficult and complex [3]. Several processes are required for accurate EMG signals classification
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