Polyhedral combinatorics, complexity and algorithms for k-clubs in graphs

Abstract

A k-club is a distance-based graph-theoretic generalization of clique, originally introduced to model cohesive subgroups in social network analysis. The k-clubs represent low diameter clusters in graphs and are suitable for various graph-based data mining applications. Unlike cliques, the k-club model is nonhereditary, meaning every subset of a k-club is not necessarily a k-club. This imposes significant challenges in developing theory and algorithms for optimization problems associated with k-clubs.We settle an open problem establishing the intractability of testing inclusion-wise maximality of k-clubs for fixed k>=2. This result is in contrast to polynomial-time verifiability of maximal cliques, and is a direct consequence of k-clubs' nonhereditary nature. A class of graphs for which this problem is polynomial-time solvable is also identified. We propose a distance coloring based upper-bounding scheme and a bounded enumeration based lower-bounding routine and employ them in a combinatorial branch-and-bound algorithm for finding a maximum k-club. Computational results on graphs with up to 200 vertices are also provided.The 2-club polytope of a graph is studied and a new family of facet inducing inequalities for this polytope is discovered. This family of facets strictly contains all known nontrivial facets of the 2-club polytope as special cases, and identifies previously unknown facets of this polytope. The separation complexity of these newly discovered facets is proved to be NP-complete and it is shown that the 2-club polytope of trees can be completely described by the collection of these facets along with the nonnegativity constraints.We also studied the maximum 2-club problem under uncertainty. Given a random graph subject to probabilistic edge failures, we are interested in finding a large "risk-averse" 2-club. Here, risk-aversion is achieved via modeling the loss in 2-club property due to edge failures, as random loss, which is a function of the decision variables and uncertain parameters. Conditional Value-at-Risk (CVaR) is used as a quantitative measure of risk that is constrained in the model. Benders' decomposition scheme is utilized to develop a new decomposition algorithm for solving the CVaR constrainedmaximum 2-club problem. A preliminary experiment is also conducted to compare the computational performance of the developed algorithm with our extension of an existing algorithm from the literature