Target Reaching Behaviour for Unfreezing the Robot in a Semi-Static and Crowded Environment

• URL: http://arxiv.org/abs/2012.01206v2
• Date: Wed, 27 Jan 2021 08:44:03 GMT
• Title: Target Reaching Behaviour for Unfreezing the Robot in a Semi-Static and Crowded Environment
• Authors: Arturo Cruz-Maya
• Abstract summary: We propose a robot behavior for a wheeled humanoid robot that complains with social norms for clearing its path when the robot is frozen due to the presence of humans. The behavior consists of two modules: 1) A detection module, which make use of the Yolo v3 algorithm trained to detect human hands and human arms, and 2) A gesture module, which make use of a policy trained in simulation using the Proximal Policy Optimization algorithm.
• Score: 2.055949720959582
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Robot navigation in human semi-static and crowded environments can lead to the freezing problem, where the robot can not move due to the presence of humans standing on its path and no other path is available. Classical approaches of robot navigation do not provide a solution for this problem. In such situations, the robot could interact with the humans in order to clear its path instead of considering them as unanimated obstacles. In this work, we propose a robot behavior for a wheeled humanoid robot that complains with social norms for clearing its path when the robot is frozen due to the presence of humans. The behavior consists of two modules: 1) A detection module, which make use of the Yolo v3 algorithm trained to detect human hands and human arms. 2) A gesture module, which make use of a policy trained in simulation using the Proximal Policy Optimization algorithm. Orchestration of the two models is done using the ROS framework.

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