Shahzad Waseem, Ayaz Yasar, Khan Muhammad Jawad, Naseer Noman, Khan Mushtaq
Department of Robotics and Intelligent Machine Engineering, School of Mechanical and Manufacturing Engineering, National University of Sciences and Technology (NUST), Islamabad, Pakistan.
National Center of Artificial Intelligence, Islamabad, Pakistan.
Front Neurorobot. 2019 Jul 3;13:43. doi: 10.3389/fnbot.2019.00043. eCollection 2019.
Control of active prosthetic hands using surface electromyography (sEMG) signals is an active research area; despite the advances in sEMG pattern recognition and classification techniques, none of the commercially available prosthetic hands provide the user with an intuitive control. One of the major reasons for this disparity between academia and industry is the variation of sEMG signals in a dynamic environment as opposed to the controlled laboratory conditions. This research investigated the effects of sEMG signal variation on the performance of a hand motion classifier due to arm position variation and also explored the effect of static position and dynamic movement strategies for classifier training. A wearable system is used to measure the electrical activity of the muscles and the position of the forearm while performing six classes of hand motions. The system is made position aware (POS) using inertial measurement units (IMUs) for different arm movement gestures. The hand gestures are decoded under both static and dynamic forearm movements. Four time domain (TD) features are extracted from the sEMG signals along with IMU-based arm position information. The features are trained and tested using linear discriminant analysis (LDA) and support vector machine (SVM) for both TD and TD-POS features. The results for the SVM show a significant difference between the static and dynamic approaches, while the TD-POS features show enhanced classification performance in comparison to the TD-based classification. Results have shown the effectiveness of the dynamic training approach and sensor fusion techniques to improve the performance of existing stand-alone sEMG-based prosthetic control systems.
利用表面肌电(sEMG)信号控制主动式假手是一个活跃的研究领域;尽管sEMG模式识别和分类技术取得了进展,但市面上现有的假手都无法为用户提供直观的控制。学术界和工业界之间存在这种差距的一个主要原因是,与受控的实验室条件相比,sEMG信号在动态环境中存在变化。本研究调查了由于手臂位置变化导致的sEMG信号变化对手部运动分类器性能的影响,还探讨了静态位置和动态运动策略对分类器训练的影响。在执行六类手部动作时,使用可穿戴系统测量肌肉的电活动和前臂的位置。该系统使用惯性测量单元(IMU)实现对不同手臂运动手势的位置感知(POS)。在静态和动态前臂运动下对手势进行解码。从sEMG信号中提取四个时域(TD)特征以及基于IMU的手臂位置信息。使用线性判别分析(LDA)和支持向量机(SVM)对TD和TD-POS特征进行训练和测试。SVM的结果表明静态和动态方法之间存在显著差异,而与基于TD的分类相比,TD-POS特征显示出更高的分类性能。结果表明了动态训练方法和传感器融合技术在提高现有基于sEMG的独立假肢控制系统性能方面的有效性。
