Proceedings of the Twenty-Eighth Annual ACM-SIAM Symposium on Discrete Algorithms 2017
DOI: 10.1137/1.9781611974782.41
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Efficient Algorithms for Constructing Very Sparse Spanners and Emulators

Abstract: Miller et al. [43] devised a distributed 1 algorithm in the CONGEST model, that given a parameter k = 1, 2, . . ., constructs an O(k)-spanner of an input unweighted nvertex graph with O(n 1+1/k ) expected edges in O(k) rounds of communication. In this paper we improve the result of [43], by showing a k-round distributed algorithm in the same model, that constructs a (2k − 1)-spanner with O(n 1+1/k / ) edges, with probability 1 − , for any > 0. Moreover, when k = ω(log n), our algorithm produces (still in k rou… Show more

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Cited by 38 publications
(157 citation statements)
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“…superclustering-and-interconnection approach (see [EP01,EN16,EN17] for an elaborate discussion of this technique). Its randomized distributed implementation by Elkin and Neiman [EN17] relies on random sampling of clusters. Those sampled clusters join nearby unsampled clusters to create superclusters, and this is iteratively repeated.…”
Section: Technical Overview and Related Work Our Algorithm Builds Upomentioning
confidence: 99%
See 2 more Smart Citations
“…superclustering-and-interconnection approach (see [EP01,EN16,EN17] for an elaborate discussion of this technique). Its randomized distributed implementation by Elkin and Neiman [EN17] relies on random sampling of clusters. Those sampled clusters join nearby unsampled clusters to create superclusters, and this is iteratively repeated.…”
Section: Technical Overview and Related Work Our Algorithm Builds Upomentioning
confidence: 99%
“…(1), and |H| = O(βn 1+1/κ ), in deterministic time O ,κ,ρ (n ρ ) in the CONGEST model. The overall structure of our algorithm is reminiscent of that in [EN17]. However, unlike the algorithm of [EN17], the current algorithm does not use any randomization.…”
Section: A Deterministic Distributed Construction Of Near-additive Spmentioning
confidence: 99%
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“…(11). As in [EN19a], we introduce an efficiency parameter ρ ∈ (0, 1] that determines the trade-off between the β value, the number of edges in the spanner, and the construction time. For a given parameter ρ, define: i 0 = log (k · ρ) , i 1 = 2/ρ − 1 , and T := i 0 + i 1 .…”
Section: B1 Efficient Constructions Of (3 + β) Spanners and Applicmentioning
confidence: 99%
“…By computing efficiently the (3 + , β) spanners, we also get the following fast computation of the S × V distances. The next is Corollary 19 of [EN19a] while enjoying a better tradeoff in the expense of increasing the multiplicative stretch from (1 + ) to (3 + ): Corollary 1. There exists an algorithm that computes for any graph G = (V, E), integer k ≥ 1, any parameters > 0, ρ ∈ (0, 1) and any vertex set S ⊆ V, a (3 + , β) approximate shortest paths for S × V, for β = O((5 + 16/ ) log ρ+2/ρ · k log(5+16/ ) ) in O((log (k · ρ) + 1/ρ) · |E| · n ρ + |S| · (n 1+1/k + (5 + 16/ ) log ρ+2/ρ · k log(5+16/ ) · n) time.…”
Section: B11 Centralized Settingmentioning
confidence: 99%