Optimal Approximation Algorithms for Maximum Distance-Bounded Subgraph Problems

Abstract

A d-clique in a graph \(G = (V, E)\) is a subset \(S\subseteq V\) of vertices such that for pairs of vertices \(u, v\in S\), the distance between u and v is at most d in G. A d-club in a graph \(G = (V, E)\) is a subset \(S'\subseteq V\) of vertices that induces a subgraph of G of diameter at most d. Given a graph G with n vertices, the goal of Max d-Clique (Max d-Club, resp.) is to find a d-clique (d-club, resp.) of maximum cardinality in G. Max 1-Clique and Max 1-Club cannot be efficiently approximated within a factor of \(n^{1-\varepsilon }\) for any \(\varepsilon > 0\) unless \(\mathcal{P} = \mathcal{NP}\) since they are identical to Max Clique [14, 21]. Also, it is known [3] that it is \(\mathcal{NP}\)-hard to approximate Max d-Club to within a factor of \(n^{1/2 - \varepsilon }\) for any fixed \(d\ge 2\) and for any \(\varepsilon > 0\). As for approximability of Max d-Club, there exists a polynomial-time algorithm which achieves an optimal approximation ratio of \(O(n^{1/2})\) for any even \(d\ge 2\) [3]. For any odd \(d\ge 3\), however, there still remains a gap between the \(O(n^{2/3})\)-approximability and the \(\varOmega (n^{1/2-\varepsilon })\)-inapproximability for Max d-Club [3]. In this paper, we first strengthen the approximability result for Max d-Club; we design a polynomial-time algorithm which achieves an optimal approximation ratio of \(O(n^{1/2})\) for Max d-Club for any odd \(d\ge 3\). Then, by using the similar ideas, we show the \(O(n^{1/2})\)-approximation algorithm for Max d-Clique on general graphs for any \(d\ge 2\). This is the best possible in polynomial time unless \(\mathcal{P} = \mathcal{NP}\), as we can prove the \(\varOmega (n^{1/2-\varepsilon })\)-inapproximability. Furthermore, we study the tractability of Max d-Clique and Max d-Club on subclasses of graphs.