The study has been published in Frontiers in Robotics and AI. “The next aim is to implement these strategies in the industrial field and test the effectiveness in different production contexts” explains Marco Controzzi, coordinator of the study
Collaborative Robotics, a study coordinated by The BioRobotics Institute reveals the grasp strategy to improve efficiency and perception of the human-robot object handover
The object handover is a fundamental phase in the cooperation between humans and robots. A study published in Frontiers in Robotics and AI reveals the grasp strategy to improve efficiency and perception of the human-robot object handover. The results of this work can benefit the wider robotics community, with application ranging from industrial to household human-robot interaction for cooperative and collaborative object manipulation.
The study is coordinated by Marco Controzzi, Assistant Professor of The BioRobotics Institute, Scuola Superiore Sant’Anna, and Investigator of APRIL Project. The other authors are Valerio Ortenzi (Max Planck Institute) e Francesca Cini (The BioRobotics Institute), Tommaso Pardi, Naresh Marturi, Rustam Stolkin (University of Birmingham) e Peter Corke (Queensland University of Technology).
In this work, the researchers investigated how different grasping strategies of a robot passer influence the performance and the perceptions of the interaction of a human receiver. This work aims to investigate how the grasping strategy of a robotic passer affects: (i) the reaching time of human receivers toward the handover location; (ii) the performance of human receivers during the execution of a subsequent task; (iii) the compensatory manipulations performed after the handover; and (iv) the receivers’ perception of the collaboration. In the experiment, twenty-two participants with no prior experience with robots were asked to grasp five test-objects from a robot and to perform a specific subsequent task with each object.
“Each object was presented individually by the robot in two different conditions: an Unaware Grasp (UG condition) or a Task-oriented Grasp (TG condition). The grasps used in UG were selected using a well-known robotic grasping algorithm based on stability considerations. Differently, grasps used in TG were hand-picked based on the task to perform after the handover.
The next step is to implement this grasp strategy in the industrial field and test the effectiveness in different production contexts. This is the principal aim of APRIL Project that will develop a new generation of robot to innovate the ways to handle flexible and deformable materials for manufacturing products in European enterprises”.