Distributed Coordination Control for Multi-Robot Networks Using Lyapunov-Like Barrier Functions

This paper addresses the problem of multi-agent coordination and control under multiple objectives, and presents a set-theoretic formulation amenable to Lyapunov-based analysis and control design. A novel class of Lyapunov-like barrier functions is introduced and used to encode multiple, non-trivial...

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Veröffentlicht in:	IEEE transactions on automatic control 2016-03, Vol.61 (3), p.617-632
Hauptverfasser:	Panagou, Dimitra, Stipanovic, Dusan M., Voulgaris, Petros G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Automatic control Barriers Collision avoidance Conflict resolution Constraints Control design Convergence Design analysis Effectiveness Encoding Maintenance Networks Robot sensing systems Safety
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creator	Panagou, Dimitra Stipanovic, Dusan M. Voulgaris, Petros G.
description	This paper addresses the problem of multi-agent coordination and control under multiple objectives, and presents a set-theoretic formulation amenable to Lyapunov-based analysis and control design. A novel class of Lyapunov-like barrier functions is introduced and used to encode multiple, non-trivial control objectives, such as collision avoidance, proximity maintenance and convergence to desired destinations. The construction is based on recentered barrier functions and on maximum approximation functions. Thus, a single Lyapunov-like function is used to encode the constrained set of each agent, yielding simple, gradient-based control solutions. The derived control strategies are distributed, i.e., based on information locally available to each agent, which is dictated by sensing and communication limitations. Furthermore, the proposed coordination protocol dictates semi-cooperative conflict resolution among agents, which can be also thought as prioritization, as well as conflict resolution with respect to an agent (the leader) which is not actively participating in collision avoidance, except when necessary. The considered scenario is pertinent to surveillance tasks and involves nonholonomic vehicles. The efficacy of the approach is demonstrated through simulation results.
doi_str_mv	10.1109/TAC.2015.2444131
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subjects	Automatic control Barriers Collision avoidance Conflict resolution Constraints Control design Convergence Design analysis Effectiveness Encoding Maintenance Networks Robot sensing systems Safety
title	Distributed Coordination Control for Multi-Robot Networks Using Lyapunov-Like Barrier Functions
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