Design of User-Independent Hand Gesture Recognition Using Multilayer Perceptron Networks and Sensor Fusion Techniques

J. G. Colli-Alfaro, Anas Ibrahim, Ana Luisa Trejos
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引用次数: 13

Abstract

According to the World Health Organization, stroke is the third leading cause of disability. A common consequence of stroke is hemiparesis, which leads to the impairment of one side of the body and affects the performance of activities of daily living. It has been proven that targeting the motor impairments as early as possible while using wearable mechatronic devices as a robot assisted therapy, and letting the patient be in control of the robotic system, can improve the rehabilitation outcomes. However, despite the increased progress on control methods for wearable mechatronic devices, a need for a more natural interface that allows for better control remains. In this work, a user-independent gesture classification method based on a sensor fusion technique using surface electromyography (EMG) and an inertial measurement unit (IMU) is presented. The Myo Armband was used to extract EMG and IMU data from healthy subjects. Participants were asked to perform 10 types of gestures in 4 different arm positions while using the Myo on their dominant limb. Data obtained from 14 participants were used to classify the gestures using a Multilayer Perceptron Network. Finally, the classification algorithm was tested on 5 novel users, obtaining an average accuracy of 78.94%. These results demonstrate that by using the proposed approach, it is possible to achieve a more natural human machine interface that allows better control of wearable mechatronic devices during robot assisted therapies.
基于多层感知器网络和传感器融合技术的用户独立手势识别设计
据世界卫生组织称,中风是致残的第三大原因。中风的一个常见后果是偏瘫,它会导致身体一侧受损,影响日常生活活动的表现。事实证明,尽早针对运动障碍,同时使用可穿戴机电设备作为机器人辅助治疗,并让患者控制机器人系统,可以改善康复效果。然而,尽管可穿戴机电设备的控制方法取得了越来越多的进展,但仍然需要一个更自然的界面来实现更好的控制。在这项工作中,提出了一种基于表面肌电图(EMG)和惯性测量单元(IMU)传感器融合技术的用户独立手势分类方法。使用Myo臂带提取健康受试者的肌电图和IMU数据。参与者被要求在他们的主要肢体上使用Myo,以4种不同的手臂姿势做10种手势。从14名参与者获得的数据被用于使用多层感知器网络对手势进行分类。最后,对5个新用户进行了分类算法测试,平均准确率为78.94%。这些结果表明,通过使用所提出的方法,可以实现更自然的人机界面,从而在机器人辅助治疗期间更好地控制可穿戴机电设备。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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