Abstract
Electromyogram (EMG)-based Pattern Recognition (PR) systems for upper-limb prosthesis control provide promising ways to enable an intuitive control of the prostheses with multiple degrees of freedom and fast reaction times. However, the lack of robustness of the PR systems may limit their usability. In this paper, a novel adaptive time windowing framework is proposed to enhance the performance of the PR systems by focusing on their windowing and classification steps. The proposed framework estimates the output probabilities of each class and outputs a movement only if a decision with a probability above a certain threshold is achieved. Otherwise (i.e., all probability values are below the threshold), the window size of the EMG signal increases. We demonstrate our framework utilizing EMG datasets collected from nine transradial amputees who performed nine movement classes with Time Domain Power Spectral Descriptors (TD-PSD), Wavelet and Time Domain (TD) feature extraction (FE) methods and a Linear Discriminant Analysis (LDA) classifier. Nonetheless, the concept can be applied to other types of features and classifiers. In addition, the proposed framework is validated with different movement and EMG channel combinations. The results indicate that the proposed framework works well with different FE methods and movement/channel combinations with classification error rates of approximately 13% with TD-PSD FE. Thus, we expect our proposed framework to be a straightforward, yet important, step towards the improvement of the control methods for upper-limb prostheses.
Highlights
In Iraq, successive wars and violent terrorist attacks have resulted in a large number of people losing their upper limbs
We utilize the information from the EMG signal to improve the performance at the expense of potentially increasing the window size
A novel adaptive windowing framework was proposed as an enhancement for the Pattern Recognition (PR) systems
Summary
In Iraq, successive wars and violent terrorist attacks have resulted in a large number of people losing their upper limbs. Sensors 2018, 18, 2402 remarkable achievements have been reached in terms of classification accuracy and the ability to control large number of movements, PR systems have been recently deployed in commercial prostheses [4] Performance degradation in real life situations due to changing arm posture [5], force variation [3] and signal non-stationarity [6] are some of the barriers which may limit the clinical implementation of PR systems This is despite a number of studies on processing methods having been tested to recognize hand movements including, for example, nonlinear measures based on recurrence plot to assess the hidden dynamical characteristics of sEMG [7] or modelling sEMG signals of hand manipulations with expectation maximization (EM) algorithms [8]
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