Repeated randomized algorithm for the Multicovering Problem

Abstract

Let H=(V,E) be a hypergraph with maximum edge size and maximum degree . For given numbers bv∈ N≥ 2, v∈ V, a set multicover in H is a set of edges C ⊂eq E such that every vertex v in V belongs to at least bv edges in C. Set multicover is the problem of finding a minimum-cardinality set multicover. Peleg, Schechtman and Wool conjectured that unless P =NP, for any fixed and b:=v∈ Vbv, no polynomial-time approximation algorithm for the Set multicover problem has an approximation ratio less than δ:=-b+1. Hence, it's a challenge to know whether the problem of set multicover is not approximable within a ratio of β δ with a constant β<1. This paper proposes a repeated randomized algorithm for the Set multicover problem combined with an initial deterministic threshold step. Boosting success by repeated trials, our algorithm yields an approximation ratio of \ 1516δ, (1- (b-1)( 3δ+18)72 )δ\. The crucial fact is not only that our result improves over the approximation ratio presented by Srivastav et al (Algorithmica 2016) for any δ≥ 13, but it's more general since we set no restriction on the parameter . Furthermore, we prove that it is NP-hard to approximate the Set multicover problem on -regular hypergraphs within a factor of (δ-1-ε). Moreover we show that the integrality gap for the Set multicover problem is at least 2(n+1)2b, which for constant b is ( n ).

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