Spreading Out: A Local Approach to Multi-robot Coverage

Batalin, Maxim; Sukhatme, Gaurav S.

doi:10.1007/978-4-431-65941-9_37

Cited by 170 publications

(110 citation statements)

References 9 publications

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“…An overview of hardware and software requirements for sensor networks can be found in [12] which describes the Berkeley Mica Motes. Algorithms for positioning a mobile sensor network includes even dispersal of sensors from a source point and redeployment for network rebuilding [2,13]. Other important contributions include [1,4,10,15,18].…”

Section: Related Workmentioning

confidence: 99%

Deployment and Connectivity Repair of a Sensor Net with a Flying Robot

Corke

Hrabar

Peterson

et al. 2006

Springer Tracts in Advanced Robotics

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Abstract. We consider multi-robot systems that include sensor nodes and aerial or ground robots networked together. Such networks are suitable for tasks such as large-scale environmental monitoring or for command and control in emergency situations. We present a sensor network deployment method using autonomous aerial vehicles and describe in detail the algorithms used for deployment and for measuring network connectivity and provide experimental data collected from field trials. A particular focus is on determining gaps in connectivity of the deployed network and generating a plan for repair, to complete the connectivity. This project is the result of a collaboration between three robotics labs (CSIRO, USC, and Dartmouth.)

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Section: Related Workmentioning

confidence: 99%

Deployment and Connectivity Repair of a Sensor Net with a Flying Robot

Corke

Hrabar

Peterson

et al. 2006

Springer Tracts in Advanced Robotics

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show abstract

“…Our coverage algorithms are distributed and robust. Batalin and Sukhatme [2] offer two coverage algorithms by a multi-robot system in which the robots spread out in the terrain, and move away from each other while covering the area and minimizing the interaction between the robots. In their work, they aim to achieve optimal coverage area, and do not prove any formal statement regarding optimality of coverage time.…”

Section: Introductionmentioning

confidence: 99%

On redundancy, efficiency, and robustness in coverage for multiple robots

Hazon

Kaminka

2008

Robotics and Autonomous Systems

113

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“…For example, in [3], Batalin and Sukhatme offer two coverage algorithms by a multi-robot system in which the robots spread out in the terrain, and move away from each other while covering the area and minimizing the interaction between the robots. In their work, they aim to achieve optimal coverage area, and do not prove any formal statement regarding optimality of coverage time.…”

Section: Introductionmentioning

confidence: 99%

The giving tree: constructing trees for efficient offline and online multi-robot coverage

Agmon

Hazon

Kaminka

2008

Ann Math Artif Intell

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This paper discusses the problem of building efficient coverage paths for a team of robots. An efficient multi-robot coverage algorithm should result in a coverage path for every robot, such that the union of all paths generates a full coverage of the terrain and the total coverage time is minimized. A method underlying several coverage algorithms, suggests the use of spanning trees as base for creating coverage paths. However, overall performance of the coverage is heavily dependent on the given spanning tree. This paper focuses on the challenge of constructing a coverage spanning tree for both online and offline coverage that minimizes the time to complete coverage. Our general approach involves building a spanning tree by growing sub-trees from the initial location of the robots. This paper first describes a polynomial time tree-construction algorithm for offline coverage. The use of this algorithm is shown by extensive simulations to significantly improve the coverage time of the terrain even when used as a basis for a simple, inefficient, coverage algorithm. Second, this paper provides an algorithm for online coverage of a finite terrain based on spanning-trees, that is complete and guarantees linear time coverage with no redundancy in the coverage. In addition, the solutions proposed by this paper guarantee robustness to failing robots: the offline trees are used as base for robust multi-robot coverage algorithms, and the online algorithm is proven to be robust.

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Spreading Out: A Local Approach to Multi-robot Coverage

Cited by 170 publications

References 9 publications

Deployment and Connectivity Repair of a Sensor Net with a Flying Robot

Deployment and Connectivity Repair of a Sensor Net with a Flying Robot

On redundancy, efficiency, and robustness in coverage for multiple robots

The giving tree: constructing trees for efficient offline and online multi-robot coverage

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