sEMG-Based Human-in-the-Loop Control of Elbow Assistive Robots for Physical Tasks and Muscle Strength Training

• Published in: IEEE robotics and automation letters Vol. 5; no. 4; pp. 5795 - 5802
• Main Authors: Meattini, Roberto, Chiaravalli, Davide, Palli, Gianluca, Melchiorri, Claudio
• Format: Journal Article
• Language: English
• Published: Piscataway IEEE 01.10.2020; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Elbow; Elbow (anatomy); electromyography; Force; human-in-the-loop; Lower bounds; Muscle strength; Muscles; Physical human-robot interaction; Physical training; physically assistive devices; rehabilitation robotics; Robot control; Robots; Service robots; Signal generation; Silicon; Sports training; Stability; Strategy; Strength training; Task analysis; Training
• ISSN: 2377-3766; 2377-3766
• DOI: 10.1109/LRA.2020.3010741

In this letter we present a sEMG-driven human-in-the-loop (HITL) control designed to allow an assistive robot produce proper support forces for both muscular effort compensations , i.e. for assistance in physical tasks, and muscular effort generations , i.e. for the application in muscle strength training exercises related to the elbow joint. By employing our control strategy based on a Double Threshold Strategy (DTS) with a standard PID regulator, we report that our approach can be successfully used to achieve a target, quantifiable muscle activity assistance. In this relation, an experimental concept validation was carried out involving four healthy subjects in physical and muscle strength training tasks, reporting with single-subject and global results that the proposed sEMG-driven control strategy was able to successfully limit the elbow muscular activity to an arbitrary level for effort compensation objectives, and to impose a lower bound to the sEMG signals during effort generation goals. Also, a subjective qualitative evaluation of the robotic assistance was carried out by means of a questionnaire. The obtained results open future possibilities for a simplified usage of the sEMG measurements to obtain a target, quantitatively defined, robot assistance for human joints and muscles.