Modalities of Sequential Human Robot Collaboration Trigger Different Modifications of Trunk Oscillations

Overview

Journal Front Neurorobot

Date 2023 Jul 10

PMID 37425334

Authors

Simone Ranaldi

Daniele Bibbo

Giovanni Corvini

Maurizio Schmid

Silvia Conforto

Affiliations

Soon will be listed here.

Abstract

Introduction: Human robot collaboration is quickly gaining importance in the robotics and ergonomics fields due to its ability to reduce biomechanical risk on the human operator while increasing task efficiency. The performance of the collaboration is typically managed by the introduction of complex algorithms in the robot control schemes to ensure optimality of its behavior; however, a set of tools for characterizing the response of the human operator to the movement of the robot has yet to be developed.

Methods: Trunk acceleration was measured and used to define descriptive metrics during various human robot collaboration strategies. Recurrence quantification analysis was used to build a compact description of trunk oscillations.

Results And Discussion: The results show that a thorough description can be easily developed using such methods; moreover, the obtained values highlight that, when designing strategies for human robot collaboration, ensuring that the subject maintains control of the rhythm of the task allows to maximize comfort in task execution, without affecting efficiency.

Citing Articles

The Impact of Human-Robot Collaboration Levels on Postural Stability During Working Tasks Performed While Standing: Experimental Study.

Bibbo D, Corvini G, Schmid M, Ranaldi S, Conforto S JMIR Hum Factors. 2025; 12:e64892.

PMID: 40014403 PMC: 11884379. DOI: 10.2196/64892.

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