Covering vertices by sequential stars

Abstract

We study the problem of covering the maximum number of vertices in a graph by a collection of vertex-disjoint stars, each with a number of satellites in a given interval [k, ], where 1 k < and can be infinity. This is referred to as sequential [k, ]-Star Packing problem. It is solvable in polynomial time when k = 1, but becomes strongly NP-hard when k 2. In this paper, we propose either the first or an improved approximation algorithm for the following four sequential settings: 1) a k+12-approximation algorithm when k 3 and = ∞, improving the previous best ratio of (k+1)22k+1; 2) a 43-approximation algorithm when k = 2 and = ∞, improving the previous best ratio of 32; 3) the first (1 + +1)-approximation algorithm when 2 = k < ; and 4) the first (1 + \ k-12, (k+1) 3 (+1)\)-approximation algorithm when 3 k < . Besides the main algorithmic techniques being local search coupled with amortized analysis, we observe augmenting configurations to bridge two distant neighborhoods for a local improvement operation. Additionally, the problem has been shown APX-hard when k 3; we prove its APX-hardness for the last remaining case where k = 2.