Leveraging High-Density EMG to Investigate Bipolar Electrode Placement for Gait Prediction Models

IF 3.5 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

IEEE Transactions on Human-Machine Systems Pub Date : 2024-03-18 DOI:10.1109/THMS.2024.3371099

Balint K. Hodossy;Annika S. Guez;Shibo Jing;Weiguang Huo;Ravi Vaidyanathan;Dario Farina

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Abstract

To control wearable robotic systems, it is critical to obtain a prediction of the user's motion intent with high accuracy. Surface electromyography (sEMG) recordings have often been used as inputs for these devices, however bipolar sEMG electrodes are highly sensitive to their location. Positional shifts of electrodes after training gait prediction models can therefore result in severe performance degradation. This study uses high-density sEMG (HD-sEMG) electrodes to simulate various bipolar electrode signals from four leg muscles during steady-state walking. The bipolar signals were ranked based on the consistency of the corresponding sEMG envelope's activity and timing across gait cycles. The locations were then compared by evaluating the performance of an offline temporal convolutional network (TCN) that mapped sEMG signals to knee angles. The results showed that electrode locations with consistent sEMG envelopes resulted in greater prediction accuracy compared to hand-aligned placements ( p < 0.01). However, performance gains through this process were limited, and did not resolve the position shift issue. Instead of training a model for a single location, we showed that randomly sampling bipolar combinations across the HD-sEMG grid during training mitigated this effect. Models trained with this method generalized over all positions, and achieved 70% less prediction error than location specific models over the entire area of the grid. Therefore, the use of HD-sEMG grids to build training datasets could enable the development of models robust to spatial variations, and reduce the impact of muscle-specific electrode placement on accuracy.

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利用高密度肌电图研究步态预测模型的双极电极位置

要控制可穿戴机器人系统，就必须高精度地预测用户的运动意图。表面肌电图（sEMG）记录通常被用作这些设备的输入，但双极 sEMG 电极对其位置高度敏感。因此，训练步态预测模型后电极位置的移动会导致严重的性能下降。本研究使用高密度 sEMG（HD-sEMG）电极模拟稳态行走过程中来自四块腿部肌肉的各种双极电极信号。根据相应的 sEMG 包络在步态周期中的活动和时间的一致性对双极信号进行排序。然后，通过评估将 sEMG 信号映射到膝关节角度的离线时间卷积网络 (TCN) 的性能，对这些位置进行比较。结果表明，与手动对齐的位置相比，具有一致 sEMG 包络线的电极位置具有更高的预测准确性（p < 0.01）。然而，通过这种方法提高的性能有限，而且没有解决位置偏移问题。我们的研究表明，在训练过程中随机抽取 HD-sEMG 网格中的双极组合，而不是针对单一位置训练模型，可以减轻这种影响。用这种方法训练的模型可以泛化到所有位置，在整个网格区域的预测误差比特定位置模型少 70%。因此，使用 HD-sEMG 网格来建立训练数据集可以开发出适应空间变化的模型，并减少特定肌肉电极位置对准确性的影响。

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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来源期刊

IEEE Transactions on Human-Machine Systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-COMPUTER SCIENCE, CYBERNETICS

CiteScore

7.10

自引率

11.10%

发文量

136

期刊介绍： The scope of the IEEE Transactions on Human-Machine Systems includes the fields of human machine systems. It covers human systems and human organizational interactions including cognitive ergonomics, system test and evaluation, and human information processing concerns in systems and organizations.