Hands are used for communicating with the surrounding environment and have a complex structure that enables them to perform various tasks with their multiple degrees of freedom. Hand amputation can prevent a person from performing their daily activities. In that event, finding a suitable, fast, and reliable alternative for the missing limb can affect the lives of people who suffer from such conditions. As the most important use of the hands is to grasp objects, the purpose of this study is to accurately predict gripping force from surface electromyography (sEMG) signals during a pinch-type grip. In that regard, gripping force and sEMG signals are derived from 10 healthy subjects. Results show that for this task, recurrent networks outperform nonrecurrent ones, such as a fully connected multilayer perceptron (MLP) network. Gated recurrent unit (GRU) and long short-term memory (LSTM) networks can predict the gripping force with R-squared values of 0.994 and 0.992, respectively, and a prediction rate of over 1300 predictions per second. The predominant advantage of using such frameworks is that the gripping force can be predicted straight from preprocessed sEMG signals without any form of feature extraction, not to mention the ability to predict future force values using larger prediction horizons adequately. The methods presented in this study can be used in the myoelectric control of prosthetic hands or robotic grippers.
翻译:手被用来与周围环境沟通,并有一个复杂的结构,使其能够以多重自由度执行各种任务。手断肢可以阻止一个人开展日常活动。在这种情况下,寻找一个合适的、快速的和可靠的替代缺失肢体的方法可以影响受此类条件影响的人的生活。由于手的最重要的用途是掌握物体,因此本研究的目的是精确地预测地表电感学信号的握力(sEMG),在紧握式控制期间,用表面电感学信号(sEMG)准确地预测握力。在这方面,握力和SEMG信号来自10个健康对象。结果显示,对于这项任务,经常网络超越非经常性网络,例如完全连接的多层透视器(MLP)网络。Gated 经常单位(GRU)和长期记忆(LSTM)网络可以预测控制力,使用R的准值分别为0.994和0.992,预测速率超过1300次。在这方面,使用这种框架的主要优势是,控制力可以从预处理前的SEMG信号直射出非经常性网络,例如完全连接的多层透视系统预测能力,而不用地平流测测测算方法。