Flocking with Obstacle Avoidance: A New Distributed Coordination Algorithm Based on Voronoi Partitions

A new distributed coordination algorithm for multi-vehicle systems is presented in this paper. The algorithm combines a particular choice of navigation function with Voronoi partitions. This results not only in obstacle avoidance and motion to the goal, but also in a desirable geographical distribut...

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Hauptverfasser:	Lindhe, M., Ogren, P., Johansson, K.H.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Centralized control Collision avoidance Control systems Convergence Flocking Lattices Multi-robot systems Navigation Obstacle avoidance Partitioning algorithms Sensor systems Shape Swarming Vehicle safety
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creator	Lindhe, M. Ogren, P. Johansson, K.H.
description	A new distributed coordination algorithm for multi-vehicle systems is presented in this paper. The algorithm combines a particular choice of navigation function with Voronoi partitions. This results not only in obstacle avoidance and motion to the goal, but also in a desirable geographical distribution of the vehicles. Our algorithm is decentralized in that each vehicle needs only to know the position of neigh boring vehicles, but no other inter-vehicle communication or centralized control are required. The algorithm gives a natural priority to safety, goal convergence, and formation keeping, in that (1) collision avoidance is guaranteed under all circumstances, (2) the vehicles will move toward the goal as long as a given optimization problem is feasible, and (3) if prior criteria admit, the vehicles tend to a desirable lattice formation. These theoretical properties are discussed in the paper and the performance of the algorithm is illustrated in simulations with realistic models of twenty all-terrain vehicles. Planned experimental evaluation using customized miniature cars is also briefly described.
doi_str_mv	10.1109/ROBOT.2005.1570372
format	Conference Proceeding
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Centralized control Collision avoidance Control systems Convergence Flocking Lattices Multi-robot systems Navigation Obstacle avoidance Partitioning algorithms Sensor systems Shape Swarming Vehicle safety
title	Flocking with Obstacle Avoidance: A New Distributed Coordination Algorithm Based on Voronoi Partitions
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