English

Hardness of Hypergraph Edge Modification Problems

Combinatorics 2025-02-11 v1 Computational Complexity

Abstract

For a fixed graph FF, let exF(G)ex_F(G) denote the size of the largest FF-free subgraph of GG. Computing or estimating exF(G)ex_F(G) for various pairs F,GF,G is one of the central problems in extremal combinatorics. It is thus natural to ask how hard is it to compute this function. Motivated by an old problem of Yannakakis from the 80's, Alon, Shapira and Sudakov [ASS'09] proved that for every non-bipartite graph FF, computing exF(G)ex_F(G) is NP-hard. Addressing a conjecture of Ailon and Alon (2007), we prove a hypergraph analogue of this theorem, showing that for every k3k \geq 3 and every non-kk-partite kk-graph FF, computing exF(G)ex_F(G) is NP-hard. Furthermore, we conjecture that our hardness result can be extended to all kk-graphs FF other than a matching of fixed size. If true, this would give a precise characterization of the kk-graphs FF for which computing exF(G)ex_F(G) is NP-hard, since we also prove that when FF is a matching of fixed size, exF(G)ex_F(G) is computable in polynomial time. This last result can be considered an algorithmic version of the celebrated Erd\H{o}s-Ko-Rado Theorem. The proof of [ASS'09] relied on a variety of tools from extremal graph theory, one of them being Tur\'an's theorem. One of the main challenges we have to overcome in order to prove our hypergraph extension is the lack of a Tur\'an-type theorem for kk-graphs. To circumvent this, we develop a completely new graph theoretic approach for proving such hardness results.

Keywords

Cite

@article{arxiv.2502.06045,
  title  = {Hardness of Hypergraph Edge Modification Problems},
  author = {Lior Gishboliner and Yevgeny Levanzov and Asaf Shapira},
  journal= {arXiv preprint arXiv:2502.06045},
  year   = {2025}
}
R2 v1 2026-06-28T21:37:57.309Z