Mutual visibility by luminous robots without collisions

Luna, Giuseppe Antonio Di; Flocchini, Paola; Chaudhuri, Sruti Gan; Poloni, Federico; Santoro, Nicola; Viglietta, Giovanni

doi:10.1016/j.ic.2016.09.005

Cited by 67 publications

(25 citation statements)

References 34 publications

(62 reference statements)

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“…The model in which robots can obstruct each other's view has also been studied. Here, the goal is typically to make all robots see each other by making sure that no three of them are collinear [17,26,27]. As with the literature on Gathering, none of these works considers robots in a polygon.…”

Section: Related Workmentioning

confidence: 99%

Meeting in a polygon by anonymous oblivious robots

et al. 2019

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The Meeting problem for k ≥ 2 searchers in a polygon P (possibly with holes) consists in making the searchers move within P , according to a distributed algorithm, in such a way that at least two of them eventually come to see each other, regardless of their initial positions. The polygon is initially unknown to the searchers, and its edges obstruct both movement and vision. Depending on the shape of P , we minimize the number of searchers k for which the Meeting problem is solvable. Specifically, if P has a rotational symmetry of order σ (where σ = 1 corresponds to no rotational symmetry), we prove that k = σ +1 searchers are sufficient, and the bound is tight. Furthermore, we give an improved algorithm that optimally solves the Meeting problem with k = 2 searchers in all polygons whose barycenter is not in a hole (which includes the polygons with no holes). Our algorithms can be implemented in a variety of standard models of mobile robots operating in Look-Compute-Move cycles. For instance, if the searchers have memory but are anonymous, asynchronous, and have no agreement on a coordinate system or a notion of clockwise direction, then our algorithms work even if the initial memory contents of the searchers are arbitrary and possibly misleading. Moreover, oblivious searchers can execute our algorithms as well, encoding information by carefully positioning themselves within the polygon. This code is computable with basic arithmetic operations (provided that the coordinates of the polygon's vertices are algebraic real numbers in some global coordinate system), and each searcher can geometrically construct its own destination point at each cycle using only a compass. We stress that such memoryless searchers may be located anywhere in the polygon when the execution begins, and hence the information they initially encode is arbitrary. Our algorithms use a self-stabilizing map construction subroutine which is of independent interest.

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Section: Related Workmentioning

confidence: 99%

Meeting in a polygon by anonymous oblivious robots

et al. 2019

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“…[21] analysed and modified the round complexities of the mutual visibility algorithms presented in [7] under fully synchronous model. Di Luna et al [22] were the first to study the mutual visibility problem in the light model. They solve the problem for the semi-synchronous robots with 3 colors and for asynchronous robots with 3 colors under one axis agreement (in [6] authors claimed a solution of the mutual visibility problem for the asynchronous robots with 10 colors.…”

Section: A Earlier Workmentioning

confidence: 99%

“…They solve the problem for the semi-synchronous robots with 3 colors and for asynchronous robots with 3 colors under one axis agreement (in [6] authors claimed a solution of the mutual visibility problem for the asynchronous robots with 10 colors. However later in [22], they modified their claim and presented a solution for the asynchronous robots with 3 colors under one axis agreement). Sharma et.…”

Section: A Earlier Workmentioning

confidence: 99%

“…have been studied extensively in the literature [17]. Recently some researchers have taken up the problem of mutual visibility [7], [22], [15], [14]. The mutual visibility problem is defined as follows: for a set of robots initially occupying distinct positions in the two dimensional plane, the mutual visibility problem asks the robots to form a configuration, within finite time and without collision, in which no three robots are collinear.…”

Section: Introductionmentioning

confidence: 99%

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Mutual Visibility by Robots with Persistent Memory

Bhagat

Mukhopadhyaya

2019

Frontiers in Algorithmics

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This paper addresses the mutual visibility problem for a set of semi-synchronous, opaque robots occupying distinct positions in the Euclidean plane. Since robots are opaque, if three robots lie on a line, the middle robot obstructs the visions of the two other robots. The mutual visibility problem asks the robots to coordinate their movements to form a configuration, within finite time and without collision, in which no three robots are collinear. Robots are endowed with a constant bits of persistent memory. In this work, we consider the FSTATE computational model in which the persistent memory is used by the robots only to remember their previous internal states. Except from this persistent memory, robots are oblivious i.e., they do not carry forward any other information from their previous computational cycles. The paper presents a distributed algorithm to solve the mutual visibility problem for a set of semi-synchronous robots using only 1 bit of persistent memory. The proposed algorithm does not impose any other restriction on the capability of the robots and guarantees collision-free movements for the robots.

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“…In [7], the authors use robots with lights and compare the computational power of such robots with respect to the three main execution model: fully-synchronous, semi-synchronous, and asynchronous. Solutions for dedicated problems such as weak gathering or mutual visibility have been respectively investigated in [15] and [16]. Mobile robot computing in infinite environments has been first studied in the continuous two-dimensional Euclidean space.…”

Section: Introductionmentioning

confidence: 99%

Infinite Grid Exploration by Disoriented Robots

Bramas

Devismes

Lafourcade

2019

Structural Information and Communication Complexity

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We deal with a set of autonomous robots moving on an infinite grid. Those robots are opaque, have limited visibility capabilities, and run using synchronous Look-Compute-Move cycles. They all agree on a common chirality, but have no global compass. Finally, they may use lights of different colors that can be seen by robots in their surroundings, but except from that, robots have neither persistent memories, nor communication mean.We consider the infinite grid exploration (IGE) problem. For this problem we give two impossibility results and three algorithms, including one which is optimal in terms of number of robots.In more detail, we first show that two robots are not sufficient in our settings to solve the problem, even when robots have a common coordinate system. We then show that if the robots' coordinate systems are not self-consistent, three or four robots are not sufficient to solve the problem neither.Finally, we present three algorithms that solve the IGE problem in various settings. The first algorithm uses six robots with constant colors and a visibility range of one. The second one uses the minimum number of robots, i.e., five, as well as five modifiable colors, still under visibility one. The last algorithm requires seven oblivious anonymous robots, yet assuming visibility two. Notice that the two last algorithms also achieve exclusiveness.

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Mutual visibility by luminous robots without collisions

Cited by 67 publications

References 34 publications

Meeting in a polygon by anonymous oblivious robots

Meeting in a polygon by anonymous oblivious robots

Mutual Visibility by Robots with Persistent Memory

Infinite Grid Exploration by Disoriented Robots

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