通过领域自适应在肌电采集系统中传输步态预测。

Annika Guez, Balint Hodossy, Dario Farina, Ravi Vaidyanathan
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引用次数: 0

摘要

下肢辅助技术(如外骨骼)可以从与生理状态相关的更高分辨率信息中显著受益。高密度肌电图(HD-EMG)网格提供了关于肌肉活动的有价值的空间信息;然而它们的硬件是不切实际的,并且双极电极在实践中仍然是标准的。利用信息丰富的HD-EMG数据集来训练机器学习模型可以帮助克服双极电极的空间限制。不幸的是,采集系统之间信号特性的差异阻碍了模型的直接传输而不会降低性能。本研究研究研究了域自适应(DA),以使基于EMG的模型对不同的采集系统保持不变。该方法使用时间卷积网络(TCN)进行评估,该网络将EMG信号映射到受试者的膝关节角度,使用HD-EMG作为源数据,使用Delsys双极EMG作为目标数据。此外,TCN学习的特征提取也应用于肌肉群,评估传感器不可知特征的可转移性。DA的实现在这两种情况下都显示出了希望,股直肌、股二头肌和胫骨前肌的准确度(通过运动范围归一化的角度误差)平均提高了7.36%,跨肌性能提高了10.80%。然而,当领域差异严重时,由于与所应用的回归方案和所选择的均方误差损失函数相关的固有限制,该模型目前无法生成可靠的行走轨迹。因此,未来的研究应侧重于探索高级损失函数和基于分类的DA模型,这些模型优先恢复步态的关键特征。
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Transferring Gait Predictors Across EMG Acquisition Systems with Domain Adaptation.

Lower limb assistive technology (e.g. exoskeletons) can benefit significantly from higher resolution information related to physiological state. High-density electromyography (HD-EMG) grids offer valuable spatial information on muscle activity; however their hardware is impractical, and bipolar electrodes remain the standard in practice. Exploiting information rich HD-EMG datasets to train machine learning models could help overcome the spatial limitations of bipolar electrodes. Unfortunately, differences in signal characteristics across acquisition systems prevent the direct transfer of models without a drop in performance. This study investigated Domain Adaptation (DA) to render EMG-based models invariant to different acquisition systems. This approach was evaluated using a Temporal Convolutional Network (TCN) that mapped EMG signals to the subject's knee angle, using HD-EMG as source data and Delsys bipolar EMG as target data. Furthermore, the feature extraction learnt by the TCN was also applied across muscle groups, evaluating the transferability of the sensor agnostic features. The DA implementation shows promise in both scenarios, with an average increase in accuracy (angular error normalised by the range of motion) of 7.36% for the Rectus Femoris, Biceps Femoris and Tibialis Anterior, as well as a cross-muscle performance increase of up to 10.80%. However, when the domain discrepancy is severe, the model is currently unable to generate a reliable walking trajectory due to inherent limitations related to the applied regression scheme and the chosen Mean Squared Error loss function. Therefore, future research should focus on exploring advanced loss functions and classification-based DA models that prioritise restoring key features of the gait.

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Individualized Three-Dimensional Gait Pattern Generator for Lower Limbs Rehabilitation Robots. Individualized Training of Back Muscles Using Iterative Learning Control of a Compliant Balance Board. Influence of Robotic Therapy on Severe Stroke Patients. INSPIIRE - A Modular and Passive Exoskeleton to Investigate Human Walking and Balance. Instrumented Upper Limb Functional Assessment Using a Robotic Exoskeleton: Normative References Intervals.
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