English

Proportionally dense subgraph of maximum size: complexity and approximation

Computational Complexity 2020-06-11 v4 Discrete Mathematics Data Structures and Algorithms

Abstract

We define a proportionally dense subgraph (PDS) as an induced subgraph of a graph with the property that each vertex in the PDS is adjacent to proportionally as many vertices in the subgraph as in the graph. We prove that the problem of finding a PDS of maximum size is APX-hard on split graphs, and NP-hard on bipartite graphs. We also show that deciding if a PDS is inclusion-wise maximal is co-NP-complete on bipartite graphs. Nevertheless, we present a simple polynomial-time (22Δ+1)(2-\frac{2}{\Delta+1})-approximation algorithm for the problem, where Δ\Delta is the maximum degree of the graph. Finally, we show that all Hamiltonian cubic graphs with nn vertices (except two) have a PDS of size 2n+13\lfloor \frac{2n+1}{3} \rfloor, which we prove to be an upper bound on the size of a PDS in cubic graphs.

Keywords

Cite

@article{arxiv.1903.06579,
  title  = {Proportionally dense subgraph of maximum size: complexity and approximation},
  author = {Cristina Bazgan and Janka Chlebíková and Clément Dallard and Thomas Pontoizeau},
  journal= {arXiv preprint arXiv:1903.06579},
  year   = {2020}
}
R2 v1 2026-06-23T08:09:28.075Z