Unobtrusive, natural support control of an adaptive industrial exoskeleton using force myography

Repetitive or tiring tasks and movements during manual work can lead to serious musculoskeletal disorders and, consequently, to monetary damage for both the worker and the employer. Among the most common of these tasks is overhead working while operating a heavy tool, such as drilling, painting, and...

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Published in:Frontiers in robotics and AI Vol. 9; p. 919370
Main Authors: Sierotowicz, Marek, Brusamento, Donato, Schirrmeister, Benjamin, Connan, Mathilde, Bornmann, Jonas, Gonzalez-Vargas, Jose, Castellini, Claudio
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 12-09-2022
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Summary:Repetitive or tiring tasks and movements during manual work can lead to serious musculoskeletal disorders and, consequently, to monetary damage for both the worker and the employer. Among the most common of these tasks is overhead working while operating a heavy tool, such as drilling, painting, and decorating. In such scenarios, it is desirable to provide adaptive support in order to take some of the load off the shoulder joint as needed. However, even to this day, hardly any viable approaches have been tested, which could enable the user to control such assistive devices naturally and in real time. Here, we present and assess the adaptive Paexo Shoulder exoskeleton, an unobtrusive device explicitly designed for this kind of industrial scenario, which can provide a variable amount of support to the shoulders and arms of a user engaged in overhead work. The adaptive Paexo Shoulder exoskeleton is controlled through machine learning applied to force myography. The controller is able to determine the lifted mass and provide the required support in real time. Twelve subjects joined a user study comparing the Paexo driven through this adaptive control to the Paexo locked in a fixed level of support. The results showed that the machine learning algorithm can successfully adapt the level of assistance to the lifted mass. Specifically, adaptive assistance can sensibly reduce the muscle activity's sensitivity to the lifted mass, with an observed relative reduction of up to 31% of the muscular activity observed when lifting 2 kg normalized by the baseline when lifting no mass.
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Joana Figueiredo, University of Minho, Portugal
This article was submitted to Biomedical Robotics, a section of the journal Frontiers in Robotics and AI
Edited by: Leonardo Gizzi, Fraunhofer Institute for Manufacturing Engineering and Automation, Germany
Reviewed by: Andrés Úbeda, University of Alicante, Spain
ISSN:2296-9144
2296-9144
DOI:10.3389/frobt.2022.919370