Donning/Doffing and Arm Positioning Influence in Upper Limb Adaptive Prostheses Control

• Published in: Applied sciences Vol. 10; no. 8; p. 2892
• Main Authors: Igual, Carles, Camacho, Andrés, Bernabeu, Enrique J., Igual, Jorge
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.04.2020
• Subjects: Adaptive filters; Algorithms; Amputation; Arm; biomedical engineering; Controllers; Digitization; Electromyography; Experiments; linear filtering; Linear filters; Muscle contraction; myoelectric signals; Myoelectricity; Prostheses; prostheses control; Prosthetics; rehabilitation; Robust control; Statistical analysis; United States > US
• ISSN: 2076-3417; 2076-3417
• DOI: 10.3390/app10082892

New upper limb prostheses controllers are continuously being proposed in the literature. However, most of the prostheses commonly used in the real world are based on very old basic controllers. One reason to explain this reluctance to change is the lack of robustness. Traditional controllers have been validated by many users and years, so the introduction of a new controller paradigm requires a lot of strong evidence of a robust behavior. In this work, we approach the robustness against donning/doffing and arm position for recently proposed linear filter adaptive controllers based on myoelectric signals. The adaptive approach allows to introduce some feedback in a natural way in real time in the human-machine collaboration, so it is not so sensitive to input signals changes due to donning/doffing and arm movements. The average completion rate and path efficiency obtained for eight able-bodied subjects donning/doffing five times in four days is 95.83% and 84.19%, respectively, and for four participants using different arm positions is 93.84% and 88.77%, with no statistically significant difference in the results obtained for the different conditions. All these characteristics make the adaptive linear regression a potential candidate for future real world prostheses controllers.