Your search keyword '"multi-robot cooperation"' showing total 2 results

1. Hitchhiking Robots: A Collaborative Approach for Efficient Multi-Robot Navigation in Indoor Environments.

Author

Ravankar, Abhijeet, Ravankar, Ankit A., Yukinori Kobayashi, and Takanori Emaru

Subjects

*OBSTACLE avoidance (Robotics), *ROBOTIC path planning, *HITCHHIKING, *NAVIGATION, *ETHANOLAMINES

Abstract

Hitchhiking is a means of transportation gained by asking other people for a (free) ride. We developed a multi-robot system which is the first of its kind to incorporate hitchhiking in robotics, and discuss its advantages. Our method allows the hitchhiker robot to skip redundant computations in navigation like path planning, localization, obstacle avoidance, and map update by completely relying on the driver robot. This allows the hitchhiker robot, which performs only visual servoing, to save computation while navigating on the common path with the driver robot. The driver robot, in the proposed system performs all the heavy computations in navigation and updates the hitchhiker about the current localized positions and new obstacle positions in the map. The proposed system is robust to recover from 'driver-lost' scenario which occurs due to visual servoing failure. We demonstrate robot hitchhiking in real environments considering factors like service-time and task priority with different start and goal configurations of the driver and hitchhiker robots. We also discuss the admissible characteristics of the hitchhiker, when hitchhiking should be allowed and when not, through experimental results. [ABSTRACT FROM AUTHOR]

Published

2017

2. Reinforcement-Learning-Based Route Generation for Heavy-Traffic Autonomous Mobile Robot Systems.

Author

Kozjek, Dominik, Malus, Andreja, and Vrabič, Rok

Subjects

*MOBILE robots, *AUTONOMOUS robots, *REINFORCEMENT learning, *SURGICAL robots, *ROBOTS

Abstract

Autonomous mobile robots (AMRs) are increasingly used in modern intralogistics systems as complexity and performance requirements become more stringent. One way to increase performance is to improve the operation and cooperation of multiple robots in their shared environment. The paper addresses these problems with a method for off-line route planning and on-line route execution. In the proposed approach, pre-computation of routes for frequent pick-up and drop-off locations limits the movements of AMRs to avoid conflict situations between them. The paper proposes a reinforcement learning approach where an agent builds the routes on a given layout while being rewarded according to different criteria based on the desired characteristics of the system. The results show that the proposed approach performs better in terms of throughput and reliability than the commonly used shortest-path-based approach for a large number of AMRs operating in the system. The use of the proposed approach is recommended when the need for high throughput requires the operation of a relatively large number of AMRs in relation to the size of the space in which the robots operate. [ABSTRACT FROM AUTHOR]

Published

2021