Bandwidth theorem for random graphs

TL;DR

This paper extends the bandwidth theorem to dense random graphs, showing that certain graphs with small bandwidth can be embedded in random graphs with high minimum degree, and provides bounds on disjoint copies.

Contribution

It generalizes the bandwidth theorem to random graphs and addresses open questions for bipartite graphs, also establishing bounds on disjoint subgraph packings.

Findings

Extension of bandwidth theorem to dense random graphs.

Resolution of an open question for bipartite graphs.

Asymptotically tight bounds on disjoint subgraph packings.

Abstract

A graph $G$ is said to have \textit{bandwidth} at most $b$, if there exists a labeling of the vertices by $1,2,..., n$, so that $|i - j| \leq b$ whenever $\{i,j\}$ is an edge of $G$. Recently, B\"{o}ttcher, Schacht, and Taraz verified a conjecture of Bollob\'{a}s and Koml\'{o}s which says that for every positive $r,\Delta,\gamma$, there exists $\beta$ such that if $H$ is an $n$-vertex $r$-chromatic graph with maximum degree at most $\Delta$ which has bandwidth at most $\beta n$, then any graph $G$ on $n$ vertices with minimum degree at least $(1 - 1/r + \gamma)n$ contains a copy of $H$ for large enough $n$. In this paper, we extend this theorem to dense random graphs. For bipartite $H$, this answers an open question of B\"{o}ttcher, Kohayakawa, and Taraz. It appears that for non-bipartite $H$ the direct extension is not possible, and one needs in addition that some vertices of $H$ have independent neighborhoods. We also obtain an asymptotically tight bound for the maximum number of vertex disjoint copies of a fixed $r$-chromatic graph $H_0$ which one can find in a spanning subgraph of $G(n,p)$ with minimum degree $(1-1/r + \gamma)np$.