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A distributed strategy for human-in-the-loop task servicing using multiple robots with stationary base station connectivity constraint

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dc.contributor.author Maini, Parikshit
dc.contributor.author Sujit, PB (Advisor)
dc.date.accessioned 2014-09-05T09:51:54Z
dc.date.available 2014-09-05T09:51:54Z
dc.date.issued 2014-09-05
dc.identifier.uri https://repository.iiitd.edu.in/jspui/handle/123456789/165
dc.description.abstract Mobile robots are increasingly being used for tasks like remote surveillance, sensing and maintenance. Some of these tasks are critical and require intelligent decision making for successful completion. It is not always possible to rely exclusively on robot level intelli- gence to make high impact decisions and hence human supervision is needed during task execution. To facilitate human-in-the-loop task servicing, the task executing robot is re- quired to remain connected to a remotely located human operator. However, robot communication range is typically limited and hence multiple mobile robots might be deployed to perform the tasks. These robots must coordinate with each other to dynamically form and maintain a communication link such that network connectivity exists between the robot servicing the task and the human operator positioned at a sta- tionary base station. The development of connectivity aware coordination algorithms is complex due to limited communication range and presence of obstacles in the search region. In this thesis, we present a distributed multi-robot algorithm for task servicing with human-in-the-loop con- straint. Robot control and mission execution is independent of the human operator and is fully autonomous. The algorithm facilitates indirect collaboration amongst the robotic agents and uses a combination of graph theoretic and gradient descent based approaches for path planning. Robots exercise independent decision making on task and role assign- ment by following a self allocation strategy. This allows dynamic task reassignments and role exchanges amongst the agents based on increased situational awareness. Our solution successfully implements obstacle avoidance and deadlock resolution while being scalable and robust to network and robot failures. To substantiate the claims, we present results from extensive simulations. en_US
dc.language.iso en_US en_US
dc.publisher IIIT Delhi en_US
dc.subject multi-robot systems en_US
dc.subject multi-agent systems en_US
dc.subject connectivity constraint en_US
dc.subject network connectivity en_US
dc.subject task allocation en_US
dc.subject base connected en_US
dc.subject networked robotics en_US
dc.subject human-in-the-loop en_US
dc.subject sta- tionary base station en_US
dc.title A distributed strategy for human-in-the-loop task servicing using multiple robots with stationary base station connectivity constraint en_US
dc.type Thesis en_US


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