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combinatorics

Completion and deficiency problems

arXiv:1904.01394

summary

The paper proves that any sparse partial Steiner triple system with at most r ≤ ε n² triples can be embedded into a complete Steiner triple system of order n + O(√r), and introduces the notion of deficiency of a graph with respect to spanning properties such as decompositions and Hamiltonicity.

Abstract

Given a partial Steiner triple system (STS) of order $n$, what is the order of the smallest complete STS it can be embedded into? The study of this question goes back more than 40 years. In this paper we answer it for relatively sparse STSs, showing that given a partial STS of order $n$ with at most $r \le \varepsilon n^2$ triples, it can always be embedded into a complete STS of order $n+O(\sqrt{r})$, which is asymptotically optimal. We also obtain similar results for completions of Latin squares and other designs. This suggests a new, natural class of questions, called deficiency problems. Given a global spanning property $\mathcal{P}$ and a graph $G$, we define the deficiency of the graph $G$ with respect to the property $\mathcal{P}$ to be the smallest positive integer $t$ such that the join $G\ast K_t$ has property $\mathcal{P}$. To illustrate this concept we consider deficiency versions of some well-studied properties, such as having a $K_k$-decomposition, Hamiltonicity, having a triangle-factor and having a perfect matching in hypergraphs. The main goal of this paper is to propose a systematic study of these problems; thus several future research directions are also given.

Topics & keywords

#steiner triple systems#design completion#deficiency problems#graph join#spanning properties#latin squarespartial Steiner triple systemembeddingO(sqrt(r)) bounddeficiencyK_k-decompositionHamiltonicitytriangle-factorhypergraph perfect matching