Variable admittance control with sEMG-based support for wearable wrist exoskeleton.

IF 2.8 4区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Frontiers in Neurorobotics Pub Date : 2025-09-01 eCollection Date: 2025-01-01 DOI:10.3389/fnbot.2025.1562675

Charles Lambelet, Melvin Mathis, Marc Siegenthaler, Jeremia P O Held, Daniel Woolley, Olivier Lambercy, Roger Gassert, Nicole Wenderoth

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引用次数: 0

Abstract

Introduction: Wrist function impairment is common after stroke and heavily impacts the execution of daily tasks. Robotic therapy, and more specifically wearable exoskeletons, have the potential to boost training dose in context-relevant scenarios, promote voluntary effort through motor intent detection, and mitigate the effect of gravity. Portable exoskeletons are often non-backdrivable and it is challenging to make their control safe, reactive and stable. Admittance control is often used in this case, however, this type of control can become unstable when the supported biological joint stiffens. Variable admittance control adapts its parameters dynamically to allow free motion and stabilize the human-robot interaction.

Methods: In this study, we implemented a variable admittance control scheme on a one degree of freedom wearable wrist exoskeleton. The damping parameter of the admittance scheme is adjusted in real-time to cope with instabilities and varying wrist stiffness. In addition to the admittance control scheme, sEMG- and gravity-based controllers were implemented, characterized and optimized on ten healthy participants and tested on six stroke survivors.

Results: The results show that (1) the variable admittance control scheme could stabilize the interaction but at the cost of a decrease in transparency, and (2) when coupled with the variable admittance controller the sEMG-based control enhanced wrist functionality of stroke survivors in the most extreme angular positions.

Discussion: Our variable admittance control scheme with sEMG- and gravity-based support was most beneficial for patients with higher levels of impairment by improving range of motion and promoting voluntary effort. Future work could combine both controllers to customize and fine tune the stability of the support to a wider range of impairment levels and types.

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可变导纳控制与肌电图为基础的支持可穿戴手腕外骨骼。

手腕功能损伤是中风后常见的，严重影响日常工作的执行。机器人疗法，更具体地说，可穿戴外骨骼，有可能在与环境相关的场景中提高训练剂量，通过运动意图检测促进自愿努力，并减轻重力的影响。便携式外骨骼通常是不可反向驱动的，使其控制安全、反应性和稳定性具有挑战性。导纳控制通常用于这种情况，然而，当支撑的生物关节变硬时，这种类型的控制会变得不稳定。变导纳控制可以动态地调整其参数以实现自由运动和稳定人机交互。方法：在本研究中，我们在一自由度可穿戴腕部外骨骼上实现了可变导纳控制方案。实时调整导纳方案的阻尼参数，以应对不稳定性和手腕刚度的变化。除了导纳控制方案外，还在10名健康参与者和6名中风幸存者身上实施、表征和优化了基于表面肌电信号和重力的控制器。结果表明：(1)可变导纳控制方案可以稳定相互作用，但以降低透明度为代价；(2)与可变导纳控制器结合使用时，基于表面肌电信号的控制可以增强中风幸存者在最极端角度位置的手腕功能。讨论：我们的可变导纳控制方案结合肌电图和重力支持，通过改善活动范围和促进自主活动，对重度损伤患者最有益。未来的工作可以结合这两个控制器来定制和微调支持的稳定性，以适应更大范围的损伤水平和类型。

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

Frontiers in Neurorobotics COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCER-ROBOTICS

CiteScore

5.20

自引率

6.50%

发文量

250

审稿时长

14 weeks

期刊介绍： Frontiers in Neurorobotics publishes rigorously peer-reviewed research in the science and technology of embodied autonomous neural systems. Specialty Chief Editors Alois C. Knoll and Florian Röhrbein at the Technische Universität München are supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics and the public worldwide. Neural systems include brain-inspired algorithms (e.g. connectionist networks), computational models of biological neural networks (e.g. artificial spiking neural nets, large-scale simulations of neural microcircuits) and actual biological systems (e.g. in vivo and in vitro neural nets). The focus of the journal is the embodiment of such neural systems in artificial software and hardware devices, machines, robots or any other form of physical actuation. This also includes prosthetic devices, brain machine interfaces, wearable systems, micro-machines, furniture, home appliances, as well as systems for managing micro and macro infrastructures. Frontiers in Neurorobotics also aims to publish radically new tools and methods to study plasticity and development of autonomous self-learning systems that are capable of acquiring knowledge in an open-ended manner. Models complemented with experimental studies revealing self-organizing principles of embodied neural systems are welcome. Our journal also publishes on the micro and macro engineering and mechatronics of robotic devices driven by neural systems, as well as studies on the impact that such systems will have on our daily life.