Robot Movement Uncertainty Determines Human Discomfort in Co-worker Scenarios
Daphne Aeraiz-Bekkis, Gowrishankar Ganesh, Eiichi Yoshida, Natsuki Yamanobe
- Year
- 2020
- Citations
- 8
Abstract
The long term success of a human-robot interaction will depend on how comfortable and safe a human feels with it. But which feature of a robot's movement determines human comfort? To address this question, here we considered four different models of human discomfort. We then designed an empirical human-robot co-worker task that enables us to both, quantify the discomfort experienced by the human co-worker by analyzing behavioral changes, and examine which model of discomfort explains the changes best. Using this task, we show that the perceived uncertainty in a robot's movement is a key determinant of human discomfort, and we discuss how movement uncertainty can give a unified explanation for the modulation of human comfort with robots, and trust in them, as reported in several previous studies.
Keywords
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