Distributed construction of purely additive spanners

Keren Censor-Hillel; Telikepalli Kavitha; Ami Paz; Amir Yehudayoff

doi:10.1007/s00446-017-0306-2

Distributed construction of purely additive spanners

Keren Censor-Hillel, Telikepalli Kavitha, Ami Paz, Amir Yehudayoff

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

This paper studies the complexity of distributed construction of purely additive spanners in the CONGEST model. We describe algorithms for building such spanners in several cases. Because of the need to simultaneously make decisions at far apart locations, the algorithms use additional mechanisms compared to their sequential counterparts. We complement our algorithms with a lower bound on the number of rounds required for computing pairwise spanners. The standard reductions from set-disjointness and equality seem unsuitable for this task because no specific edge needs to be removed from the graph. Instead, to obtain our lower bound, we define a new communication complexity problem that reduces to computing a sparse spanner, and prove a lower bound on its communication complexity. This technique significantly extends the current toolbox used for obtaining lower bounds for the CONGEST model, and we believe it may find additional applications.

Original language	English
Pages (from-to)	223-240
Number of pages	18
Journal	Distributed Computing
Volume	31
Issue number	3
DOIs	https://doi.org/10.1007/s00446-017-0306-2
State	Published - 1 Jun 2018

All Science Journal Classification (ASJC) codes

Theoretical Computer Science
Hardware and Architecture
Computer Networks and Communications
Computational Theory and Mathematics

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10.1007/s00446-017-0306-2

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title = "Distributed construction of purely additive spanners",

abstract = "This paper studies the complexity of distributed construction of purely additive spanners in the CONGEST model. We describe algorithms for building such spanners in several cases. Because of the need to simultaneously make decisions at far apart locations, the algorithms use additional mechanisms compared to their sequential counterparts. We complement our algorithms with a lower bound on the number of rounds required for computing pairwise spanners. The standard reductions from set-disjointness and equality seem unsuitable for this task because no specific edge needs to be removed from the graph. Instead, to obtain our lower bound, we define a new communication complexity problem that reduces to computing a sparse spanner, and prove a lower bound on its communication complexity. This technique significantly extends the current toolbox used for obtaining lower bounds for the CONGEST model, and we believe it may find additional applications.",

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AB - This paper studies the complexity of distributed construction of purely additive spanners in the CONGEST model. We describe algorithms for building such spanners in several cases. Because of the need to simultaneously make decisions at far apart locations, the algorithms use additional mechanisms compared to their sequential counterparts. We complement our algorithms with a lower bound on the number of rounds required for computing pairwise spanners. The standard reductions from set-disjointness and equality seem unsuitable for this task because no specific edge needs to be removed from the graph. Instead, to obtain our lower bound, we define a new communication complexity problem that reduces to computing a sparse spanner, and prove a lower bound on its communication complexity. This technique significantly extends the current toolbox used for obtaining lower bounds for the CONGEST model, and we believe it may find additional applications.

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JO - Distributed Computing

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Distributed construction of purely additive spanners

Abstract

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