Independence, induced subgraphs, and domination in $K_{1,r}$-free graphs

TL;DR

This paper establishes bounds on the independence and induced subgraph sizes in $K_{1,r}$-free graphs, relating them to domination numbers and extending results via Ramsey theory, with tight bounds for specific cases.

Contribution

It introduces new bounds on independence and induced subgraph sizes in $K_{1,r}$-free graphs, generalizing and extending previous results using Ramsey theory and graph parameters.

Findings

Bound $ ext{α}_ ext{F}(G) ext{ in terms of } ext{γ}(G)$ for $K_{1,r}$-free graphs.

Simplified bound $ ext{α}(G) ext{ for claw-free graphs}$.

Extended bounds using Ramsey theory for edge-hereditary families.

Abstract

Let $G$ be a graph and $\mathcal{F}$ a family of graphs. Define $\alpha_{\mathcal{F}}(G)$ as the maximum order of any induced subgraph of $G$ that belongs to the family $\mathcal{F}$. For the family $\mathcal{F}$ of graphs with \emph{chromatic number} at most~$k$, we prove that if $G$ is $K_{1,r}$-free, then $\alpha_{\mathcal{F}}(G) \le (r-1)k\gamma(G)$, where $\gamma(G)$ is the \emph{domination number}. When $\mathcal{F}$ is the family of empty graphs, this bound simplifies to $\alpha(G) \le 2\gamma(G)$ for $K_{1,3}$-free (claw-free) graphs, where $\alpha(G)$ is the \emph{independence number} of $G$. For $d$-regular graphs, this is further refined to the bound $\alpha(G) \le 2\left(\frac{d+1}{d+2}\right)\gamma(G)$, which is tight for $d \in \{2, 3, 4\}$. Using Ramsey theory, we extend this framework to edge-hereditary graph families, showing that for $K_{1,r}$-free graphs, we have $\alpha_{\mathcal{F}}(G) \le r(K_r, \mathcal{F^*})\gamma(G)$, where $\mathcal{F^*}$ is the set of graphs not in $\mathcal{F}$. Specializing to $K_q$-free graphs, we show $\alpha_{\mathcal{F}}(G) \le (r(K_q, K_r) - 1)\gamma(G)$. Finally, for the \emph{$k$-independence number} $\alpha_k(G)$, we prove that if $G$ is $K_{1,r}$-free with order $n$ and minimum degree $\delta \ge k+1$, \[ \alpha_k(G) \le \left( \frac{(r-1)(k+1)}{\delta - k + (r-1)(k+1)} \right) n, \] and this bound is sharp for all parameters.