Elsevier

Discrete Applied Mathematics

Volume 199, 30 January 2016, Pages 101-109
Discrete Applied Mathematics

On the complexity of the shortest-path broadcast problem

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Abstract

We study the shortest-path broadcast problem in graphs and digraphs, where a message has to be transmitted from a source node s to all the nodes along shortest paths, in the classical telephone model. For both graphs and digraphs, we show that the problem is equivalent to the broadcast problem in layered directed graphs. We then prove that this latter problem is NP-hard, and therefore that the shortest-path broadcast problem is NP-hard in graphs as well as in digraphs. Nevertheless, we prove that a simple polynomial-time algorithm, called MDST-broadcast, based on min-degree spanning trees, approximates the optimal broadcast time within a multiplicative factor  32 in 3-layer digraphs, and O(lognloglogn) in arbitrary multi-layer digraphs. As a consequence, one can approximate the optimal shortest-path broadcast time in polynomial time within a multiplicative factor  32 whenever the source has eccentricity at most 2, and within a multiplicative factor  O(lognloglogn) in the general case, for both graphs and digraphs. The analysis of MDST-broadcast is tight, as we prove that this algorithm cannot approximate the optimal broadcast time within a factor smaller than Ω(lognloglogn).

Keywords

Broadcast time
Shortest paths
Communication networks
Layered graphs

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