An Improved Approximation Algorithm for the Maximum Weight Independent Set Problem in d-Claw Free Graphs
Abstract
In this paper, we consider the task of computing an independent set of maximum weight in a given d-claw free graph G=(V,E) equipped with a positive weight function w:V→R+. In doing so, d≥ 2 is considered a constant. The previously best known approximation algorithm for this problem is the local improvement algorithm SquareImp proposed by Berman. It achieves a performance ratio of d2+ε in time O(|V(G)|d+1·(|V(G)|+|E(G)|)· (d-1)2· (d2ε+1)2) for any ε>0, which has remained unimproved for the last twenty years. By considering a broader class of local improvements, we obtain an approximation ratio of d2-163,700,992+ε for any ε>0 at the cost of an additional factor of O(|V(G)|(d-1)2) in the running time. In particular, our result implies a polynomial time d2-approximation algorithm. Furthermore, the well-known reduction from the weighted k-Set Packing Problem to the Maximum Weight Independent Set Problem in k+1-claw free graphs provides a k+12-163,700,992+ε-approximation algorithm for the weighted k-Set Packing Problem for any ε>0. This improves on the previously best known approximation guarantee of k+12+ε originating from the result of Berman.
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