English

Problems, proofs, and disproofs on the inversion number

Combinatorics 2022-12-26 v3 Discrete Mathematics

Abstract

The {\it inversion} of a set XX of vertices in a digraph DD consists in reversing the direction of all arcs of DXD\langle X\rangle. The {\it inversion number} of an oriented graph DD, denoted by inv(D){\rm inv}(D), is the minimum number of inversions needed to transform DD into an acyclic oriented graph. In this paper, we study a number of problems involving the inversion number of oriented graphs. Firstly, we give bounds on inv(n){\rm inv}(n), the maximum of the inversion numbers of the oriented graphs of order nn. We show nO(nlogn)  inv(n)  nlog(n+1)n - \mathcal{O}(\sqrt{n\log n}) \ \leq \ {\rm inv}(n) \ \leq \ n - \lceil \log (n+1) \rceil. Secondly, we disprove a conjecture of Bang-Jensen et al. asserting that, for every pair of oriented graphs LL and RR, we have inv(LR)=inv(L)+inv(R){\rm inv}(L\Rightarrow R) ={\rm inv}(L) + {\rm inv}(R), where LRL\Rightarrow R is the oriented graph obtained from the disjoint union of LL and RR by adding all arcs from LL to RR. Finally, we investigate whether, for all pairs of positive integers k1,k2k_1,k_2, there exists an integer f(k1,k2)f(k_1,k_2) such that if DD is an oriented graph with inv(D)f(k1,k2){\rm inv}(D) \geq f(k_1,k_2) then there is a partition (V1,V2)(V_1, V_2) of V(D)V(D) such that inv(DVi)ki{\rm inv}(D\langle V_i\rangle) \geq k_i for i=1,2i=1,2. We show that f(1,k)f(1,k) exists and f(1,k)k+10f(1,k)\leq k+10 for all positive integers kk. Further, we show that f(k1,k2)f(k_1,k_2) exists for all pairs of positive integers k1,k2k_1,k_2 when the oriented graphs in consideration are restricted to be tournaments.

Keywords

Cite

@article{arxiv.2212.09188,
  title  = {Problems, proofs, and disproofs on the inversion number},
  author = {Guillaume Aubian and Frédéric Havet and Florian Hörsch and Felix Klingelhoefer and Nicolas Nisse and Clément Rambaud and Quentin Vermande},
  journal= {arXiv preprint arXiv:2212.09188},
  year   = {2022}
}
R2 v1 2026-06-28T07:41:15.798Z