The size Ramsey number of short subdivisions of bounded degree graphs

Yoshiharu Kohayakawa; Troy Retter; Vojtěch Rödl

doi:10.1002/rsa.20783

Size Ramsey Number of Bounded Degree Graphs for Games

Combinatorics Probability Computing ◽

10.1017/s0963548313000151 ◽

2013 ◽

Vol 22 (4) ◽

pp. 499-516

Author(s):

HEIDI GEBAUER

Keyword(s):

Connected Graph ◽

Maximum Degree ◽

Ramsey Number ◽

Bounded Degree ◽

Minimum Number ◽

Game Theoretic ◽

Bounded Degree Graphs ◽

Constant Maximum

We study Maker/Breaker games on the edges ofsparsegraphs. Maker and Breaker take turns at claiming previously unclaimed edges of a given graphH. Maker aims to occupy a given target graphGand Breaker tries to prevent Maker from achieving his goal. We show that for everydthere is a constantc=c(d)with the property that for every graphGonnvertices of maximum degreedthere is a graphHon at mostcnedges such that Maker has a strategy to occupy a copy ofGin the game onH.This is a result about a game-theoretic variant of the size Ramsey number. For a given graphG,$\hat{r}'(G)$is defined as the smallest numberMfor which there exists a graphHwithMedges such that Maker has a strategy to occupy a copy ofGin the game onH. In this language, our result yields that for every connected graphGof constant maximum degree,$\hat{r}'(G) = \Theta(n)$.Moreover, we can also use our method to settle the corresponding extremal number foruniversalgraphs: for a constantdand for the class${\cal G}_{n}$ofn-vertex graphs of maximum degreed,$s({\cal G}_{n})$denotes the minimum number such that there exists a graphHwithMedges where, foreveryG∈${\cal G}_{n}$, Maker has a strategy to build a copy ofGin the game onH. We obtain that$s({\cal G}_{n}) = \Theta(n^{2 - \frac{2}{d}})$.

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Degree Ramsey Numbers of Graphs

Combinatorics Probability Computing ◽

10.1017/s0963548311000617 ◽

2012 ◽

Vol 21 (1-2) ◽

pp. 229-253 ◽

Cited By ~ 3

Author(s):

WILLIAM B. KINNERSLEY ◽

KEVIN G. MILANS ◽

DOUGLAS B. WEST

Keyword(s):

Maximum Degree ◽

Double Star ◽

Ramsey Number ◽

Bounded Degree ◽

Ramsey Numbers ◽

Colour Class ◽

Bounded Degree Graphs ◽

Edge Colourings ◽

Edge Colouring ◽

Monochromatic Copy

Let HG mean that every s-colouring of E(H) produces a monochromatic copy of G in some colour class. Let the s-colour degree Ramsey number of a graph G, written RΔ(G; s), be min{Δ(H): HG}. If T is a tree in which one vertex has degree at most k and all others have degree at most ⌈k/2⌉, then RΔ(T; s) = s(k − 1) + ϵ, where ϵ = 1 when k is odd and ϵ = 0 when k is even. For general trees, RΔ(T; s) ≤ 2s(Δ(T) − 1).To study sharpness of the upper bound, consider the double-starSa,b, the tree whose two non-leaf vertices have degrees a and b. If a ≤ b, then RΔ(Sa,b; 2) is 2b − 2 when a < b and b is even; it is 2b − 1 otherwise. If s is fixed and at least 3, then RΔ(Sb,b;s) = f(s)(b − 1) − o(b), where f(s) = 2s − 3.5 − O(s−1).We prove several results about edge-colourings of bounded-degree graphs that are related to degree Ramsey numbers of paths. Finally, for cycles we show that RΔ(C2k + 1; s) ≥ 2s + 1, that RΔ(C2k; s) ≥ 2s, and that RΔ(C4;2) = 5. For the latter we prove the stronger statement that every graph with maximum degree at most 4 has a 2-edge-colouring such that the subgraph in each colour class has girth at least 5.

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On-line Ramsey Theory for Bounded Degree Graphs

The Electronic Journal of Combinatorics ◽

10.37236/623 ◽

2011 ◽

Vol 18 (1) ◽

Cited By ~ 9

Author(s):

Jane Butterfield ◽

Tracy Grauman ◽

William B. Kinnersley ◽

Kevin G. Milans ◽

Christopher Stocker ◽

...

Keyword(s):

Ramsey Theory ◽

Upper Bounds ◽

Ramsey Number ◽

Bounded Degree ◽

Linear Forest ◽

On Line ◽

Bounded Degree Graphs ◽

Vertex Degrees ◽

Delta G ◽

Monochromatic Copy

When graph Ramsey theory is viewed as a game, "Painter" 2-colors the edges of a graph presented by "Builder". Builder wins if every coloring has a monochromatic copy of a fixed graph $G$. In the on-line version, iteratively, Builder presents one edge and Painter must color it. Builder must keep the presented graph in a class ${\cal H}$. Builder wins the game $(G,{\cal H})$ if a monochromatic copy of $G$ can be forced. The on-line degree Ramsey number $\mathring {R}_\Delta(G)$ is the least $k$ such that Builder wins $(G,{\cal H})$ when ${\mathcal H}$ is the class of graphs with maximum degree at most $k$. Our results include: 1) $\mathring {R}_\Delta(G)\!\le\!3$ if and only if $G$ is a linear forest or each component lies inside $K_{1,3}$. 2) $\mathring {R}_\Delta(G)\ge \Delta(G)+t-1$, where $t=\max_{uv\in E(G)}\min\{d(u),d(v)\}$. 3) $\mathring {R}_\Delta(G)\le d_1+d_2-1$ for a tree $G$, where $d_1$ and $d_2$ are two largest vertex degrees. 4) $4\le \mathring {R}_\Delta(C_n)\le 5$, with $\mathring {R}_\Delta(C_n)=4$ except for finitely many odd values of $n$. 5) $\mathring {R}_\Delta(G)\le6$ when $\Delta(G)\le 2$. The lower bounds come from strategies for Painter that color edges red whenever the red graph remains in a specified class. The upper bounds use a result showing that Builder may assume that Painter plays "consistently".

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