English

Partitioning a graph into a cycle and a sparse graph

Combinatorics 2016-07-26 v2

Abstract

In this paper we investigate results of the form "every graph GG has a cycle CC such that the induced subgraph of GG on V(G)V(C)V(G)\setminus V(C) has small maximum degree." Such results haven't been studied before, but are motivated by the Bessy and Thomass\'e Theorem which states that the vertices of any graph GG can be covered by a cycle C1C_1 in GG and disjoint cycle C2C_2 in the complement of GG. There are two main theorems in this paper. The first is that every graph has a cycle with Δ(G[V(G)V(C)])12(V(G)V(C)1)\Delta(G[V(G)\setminus V(C)])\leq \frac12(|V(G)\setminus V(C)|-1). The bound on the maximum degree Δ(G[V(G)V(C)])\Delta(G[V(G)\setminus V(C)]) is best possible. The second theorem is that every kk-connected graph GG has a cycle with Δ(G[V(G)V(C)])1k+1V(G)V(C)+3\Delta(G[V(G)\setminus V(C)])\leq \frac1{k+1}|V(G)\setminus V(C)|+3. We also give an application of this second theorem to a conjecture about partitioning edge-coloured complete graphs into monochromatic cycles.

Keywords

Cite

@article{arxiv.1607.03348,
  title  = {Partitioning a graph into a cycle and a sparse graph},
  author = {Alexey Pokrovskiy},
  journal= {arXiv preprint arXiv:1607.03348},
  year   = {2016}
}

Comments

26 pages, 6 figures

R2 v1 2026-06-22T14:52:21.957Z