English

Various Theorems on Tournaments

Combinatorics 2012-07-03 v1

Abstract

In this thesis we prove a variety of theorems on tournaments. A \emph{prime} tournament is a tournament GG such that there is no XV(G)X \subseteq V(G), 1<X<V(G)1 < |X| < |V(G)|, such that for every vertex vV(G)\minusXv \in V(G) \minus X, either v\raxv \ra x for all xXx \in X or x\ravx \ra v for all xXx \in X. First, we prove that given a prime tournament GG which is not in one of three special families of tournaments, for any prime subtournament HH of GG with 5V(H)<V(G)5 \le |V(H)| < |V(G)| there exists a prime subtournament of GG with V(H)+1|V(H)| + 1 vertices that has a subtournament isomorphic to HH. We next prove that for any two cyclic triangles CC, CC^\prime in a prime tournament GG, there is a sequence of cyclic triangles C1,...,CnC_1,...,C_n such that C1=CC_1 = C, Cn=CC_n = C^\prime, and CiC_i shares an edge with Ci+1C_{i+1} for all 1in11 \le i \le n-1. Next, we consider what we call \emph{matching tournaments}, tournaments whose vertices can be ordered in a horizontal line so that every vertex is the head or tail of at most one edge that points right-to-left. We determine the conditions under which a tournament can have two different orderings satisfying the above conditions. We also prove that there are infinitely many minimal tournaments that are not matching tournaments. Finally, we consider the tournaments KnK_n and KnK_n^\ast, which are obtained from the transitive tournament with nn vertices by reversing the edge from the second vertex to the last vertex and from the first vertex to the second-to-last vertex, respectively. We prove a structure theorem describing tournaments which exclude KnK_n and KnK_n^\ast as subtournaments.

Keywords

Cite

@article{arxiv.1207.0237,
  title  = {Various Theorems on Tournaments},
  author = {Gaku Liu},
  journal= {arXiv preprint arXiv:1207.0237},
  year   = {2012}
}

Comments

Undergraduate senior thesis, adviser Paul Seymour

R2 v1 2026-06-21T21:28:48.616Z