Modeling contact forces during human-robot interactions for performing activities of daily living

• Published in: Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine Vol. 237; no. 7; pp. 829 - 840
• Main Authors: Bilyea, Aubrianna JN, French, Steven H, Abdullah, Hussein A
• Format: Journal Article
• Language: English
• Published: London, England SAGE Publications 01.07.2023
• Subjects: Activities of Daily Living; Humans; Mechanical Phenomena; Robotics; assistive device; Human-robot interactions; contact force; personal care robot; activities of daily living
• ISSN: 0954-4119; 2041-3033
• DOI: 10.1177/09544119231179568

This study aims to characterize contact forces between humans and tools during activities of daily living (ADL) to provide information to a personal care robot. The study was conducted on non-impaired subjects to capture various static and dynamic force levels when making contact with three different robotic tools, each designed to perform an ADL task: hair brushing, face wiping, and face shaving. The static trial of the study involved 21 participants. Forces were collected at fixed locations for each task and used to develop models for each participant. Extraction of the maximum force levels was performed for both the maximum and desired levels of force. The dynamic trial involved 24 individuals. Participants were asked to maintain a comfortable level of force for the duration of their contact with the tool as the robot moved along its path to perform the ADL task. For the static and dynamic trials, higher forces were observed during hair brushing compared to the other two tasks. It was observed that the hair brushing task force at a specific contact point has an overall maximum of 55.66 N, while the maximum forces detected in the face wiping and face shaving tasks were 36.40 and 11.11 N, respectively. The forces collected were analyzed, and no trends were found relating the contact forces to the gender, height, or weight of the subjects. Based on the analysis of the results, recommendations have been made to enhance the force safety limits for the personal care robot working environment.