English

Solving the Multiobjective Quasi-Clique Problem

Discrete Mathematics 2026-02-26 v2 Data Structures and Algorithms

Abstract

Given a simple undirected graph GG, a quasi-clique is a subgraph of GG whose density is at least γ\gamma (0<γ1)(0 < \gamma \leq 1). Finding a maximum quasi-clique has been addressed from two different perspectives: i)i) maximizing vertex cardinality for a given edge density; and ii)ii) maximizing edge density for a given vertex cardinality. However, when no a priori preference information about cardinality and density is available, a more natural approach is to consider the problem from a multiobjective perspective. We introduce the Multiobjective Quasi-clique Problem (MOQC), which aims to find a quasi-clique by simultaneously maximizing both vertex cardinality and edge density. To efficiently address this problem, we explore the relationship among MOQC, its single-objective counterpart problems, and a biobjective optimization problem, along with several properties of the MOQC problem and quasi-cliques. We propose a baseline approach using ε\varepsilon-constraint scalarization and introduce a Two-phase strategy, which applies a dichotomic search based on weighted sum scalarization in the first phase and an ε\varepsilon-constraint methodology in the second phase. Additionally, we present a Three-phase strategy that combines the dichotomic search used in Two-phase with a vertex-degree-based local search employing novel sufficient conditions to assess quasi-clique efficiency, followed by an ε\varepsilon-constraint in a final stage. Experimental results on real-world sparse graphs indicate that the integrated use of dichotomic search and local search, together with mechanisms to assess quasi-clique efficiency, makes the Three-phase strategy an effective approach for solving the MOQC problem in terms of running time and ability to produce new efficient quasi-cliques.

Keywords

Cite

@article{arxiv.2403.10896,
  title  = {Solving the Multiobjective Quasi-Clique Problem},
  author = {Daniela Scherer dos Santos and Kathrin Klamroth and Pedro Martins and Luís Paquete},
  journal= {arXiv preprint arXiv:2403.10896},
  year   = {2026}
}
R2 v1 2026-06-28T15:22:45.026Z