Distributed computing by mobile robots: uniform circle formation

Consider a set of n finite set of simple autonomous mobile robots (asynchronous, no common coordinate system, no identities, no central coordination, no direct communication, no memory of the past, non-rigid, deterministic) initially in distinct locations, moving freely in the plane and able to sens...

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Bibliographic Details
Published in:Distributed computing 2017-12, Vol.30 (6), p.413-457
Main Authors: Flocchini, Paola, Prencipe, Giuseppe, Santoro, Nicola, Viglietta, Giovanni
Format: Article
Language:English
Subjects:
Chirality
Communications systems
Computer Communication Networks
Computer Hardware
Computer networks
Computer Science
Computer Systems Organization and Communication Networks
Distributed processing
Mobile computing
Robots
Software Engineering/Programming and Operating Systems
Theory of Computation
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Summary:Consider a set of n finite set of simple autonomous mobile robots (asynchronous, no common coordinate system, no identities, no central coordination, no direct communication, no memory of the past, non-rigid, deterministic) initially in distinct locations, moving freely in the plane and able to sense the positions of the other robots. We study the primitive task of the robots arranging themselves on the vertices of a regular n -gon not fixed in advance ( Uniform Circle Formation ). In the literature, the existing algorithmic contributions are limited to conveniently restricted sets of initial configurations of the robots and to more powerful robots. The question of whether such simple robots could deterministically form a uniform circle has remained open. In this paper, we constructively prove that indeed the Uniform Circle Formation problem is solvable for any initial configuration in which the robots are in distinct locations, without any additional assumption (if two robots are in the same location, the problem is easily seen to be unsolvable). In addition to closing a long-standing problem, the result of this paper also implies that, for pattern formation, asynchrony is not a computational handicap, and that additional powers such as chirality and rigidity are computationally irrelevant.
ISSN:0178-2770
1432-0452
DOI:10.1007/s00446-016-0291-x