用于连续运动估计的新型肌肉协同方法在未训练运动中的表现(2024 年 3 月)

IF 4.8 2区 医学 Q2 ENGINEERING, BIOMEDICAL
Wenjuan Lu;Huiting Ma;Daxing Zeng
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引用次数: 0

摘要

在人机系统中应用基于 sEMG 的连续运动估计(CME)模型时,不可避免地会遇到用户执行的运动与模型训练阶段的运动不同的情况。事实证明,目前有效的方法对未经训练的动作的预测准确性将大大降低。因此,我们提出了一种新颖的 CME 方法,引入肌肉协同作用作为特征,从而在未经训练的运动任务中获得更好的预测精度。具体来说,首先在协同作用提取中引入深度非光滑 NMF(Deep-nsNMF),以提高协同作用分解的效率。从各种训练动作中获取激活基元后,我们提出了一种冗余分类算法(RC)来识别共享协同和特定任务协同,优化了原有的冗余分割算法(RS)。我们将 NARX 神经网络设定为训练回归模型。最后,该模型在八个未训练动作的预测任务中进行了测试。结果发现,与使用时域特征作为网络的输入相比,所提出方法的预测精度更高。带有 RS 的 Deep-nsNMF 预测准确率最高,达到 99.7%。使用 RC 的 Deep-nsNMF 也有类似的表现,其稳定性在不同运动和受试者中也相对较高。该方法的局限性在于预测误差与实际角度绝对值之间的正相关问题仍有待进一步解决。总体而言,这项研究证明了 CME 模型在复杂场景中表现良好的潜力,为 CME 在现实世界中的应用提供了可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance of a Novel Muscle Synergy Approach for Continuous Motion Estimation on Untrained Motion
When applying continuous motion estimation (CME) model based on sEMG to human-robot system, it is inevitable to encounter scenarios in which the motions performed by the user are different from the motions in the training stage of the model. It has been demonstrated that the prediction accuracy of the currently effective approaches on untrained motions will be significantly reduced. Therefore, we proposed a novel CME method by introducing muscle synergy as feature to achieve better prediction accuracy on untrained motion tasks. Specifically, deep non-smooth NMF (Deep-nsNMF) was firstly introduced on synergy extraction to improve the efficiency of synergy decomposition. After obtaining the activation primitives from various training motions, we proposed a redundancy classification algorithm (RC) to identify shared and task-specific synergies, optimizing the original redundancy segmentation algorithm (RS). NARX neural network was set as the regression model for training. Finally, the model was tested on prediction tasks of eight untrained motions. The prediction accuracy of the proposed method was found to perform better than using time-domain feature as input of the network. Through Deep-nsNMF with RS, the highest accuracy reached 99.7%. Deep-nsNMF with RC performed similarly well and its stability was relatively higher among different motions and subjects. Limitation of the approach is that the problem of positive correlation between the prediction error and the absolute value of real angle remains to be further addressed. Generally, this research demonstrates the potential for CME models to perform well in complex scenarios, providing the feasibility of dedicating CME to real-world applications.
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来源期刊
CiteScore
8.60
自引率
8.20%
发文量
479
审稿时长
6-12 weeks
期刊介绍: Rehabilitative and neural aspects of biomedical engineering, including functional electrical stimulation, acoustic dynamics, human performance measurement and analysis, nerve stimulation, electromyography, motor control and stimulation; and hardware and software applications for rehabilitation engineering and assistive devices.
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