Efficient Defective Clique Enumeration and Search with Worst-Case Optimal Search Space
Abstract
A k-defective clique is a relaxation of the traditional clique definition, allowing up to k missing edges. This relaxation is crucial in various real-world applications such as link prediction, community detection, and social network analysis. Although the problems of enumerating maximal k-defective cliques and searching a maximum k-defective clique have been extensively studied, existing algorithms suffer from limitations such as the combinatorial explosion of small partial solutions and sub-optimal search spaces. To address these limitations, we propose a novel clique-first branch-and-bound framework that first generates cliques and then adds missing edges. Furthermore, we introduce a new pivoting technique that achieves a search space size of O(3n3 · nk), where n is the number of vertices in the input graph. We prove that the worst-case number of maximal k-defective cliques is (3n3 · nk) when k is a constant, establishing that our algorithm's search space is worst-case optimal. Leveraging the diameter-two property of defective cliques, we further reduce the search space size to O(n · 3δ3 · (δ )k), where δ is the degeneracy and is the maximum degree of the input graph. We also propose an efficient framework for maximum k-defective clique search based on our branch-and-bound, together with practical techniques to reduce the search space. Experiments on real-world benchmark datasets with more than 1 million edges demonstrate that each of our proposed algorithms for maximal k-defective clique enumeration and maximum k-defective clique search outperforms the respective state-of-the-art algorithms by up to four orders of magnitude in terms of processing time.
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