English

Spanning eulerian subdigraphs avoiding k prescribed arcs in tournaments

Combinatorics 2019-07-02 v1

Abstract

A digraph is {\bf eulerian} if it is connected and every vertex has its in-degree equal to its out-degree. Having a spanning eulerian subdigraph is thus a weakening of having a hamiltonian cycle. A digraph is {\bf semicomplete} if it has no pair of non-adjacent vertices. A {\bf tournament} is a semicomplete digraph without directed cycles of length 2. Fraise and Thomassen \cite{fraisseGC3} proved that every (k+1)(k+1)-strong tournament has a hamiltonian cycle which avoids any prescribed set of kk arcs. In \cite{bangsupereuler} the authors demonstrated that a number of results concerning vertex-connectivity and hamiltonian cycles in tournaments and have analogues when we replace vertex connectivity by arc-connectivity and hamiltonian cycles by spanning eulerian subdigraphs. They showed the existence of a smallest function f(k)f(k) such that every f(k)f(k)-arc-strong semicomplete digraph has a spanning eulerian subdigraph which avoids any prescribed set of kk arcs. They proved that f(k)(k+1)24+1f(k)\leq \frac{(k+1)^2}{4}+1 and also proved that f(k)=k+1f(k)=k+1 when k=2,3k=2,3. Based on this they conjectured that f(k)=k+1f(k)=k+1 for all k0k\geq 0. In this paper we prove that f(k)(6k+15)f(k)\leq (\lceil\frac{6k+1}{5}\rceil).

Keywords

Cite

@article{arxiv.1907.00853,
  title  = {Spanning eulerian subdigraphs avoiding k prescribed arcs in tournaments},
  author = {Jørgen Bang-Jensen and Hugues Depres and Anders Yeo},
  journal= {arXiv preprint arXiv:1907.00853},
  year   = {2019}
}
R2 v1 2026-06-23T10:08:53.262Z