📝 SummarXiv

Abstract

It is well known that the spectral radius $\rho(T)$ of a tree $T$ with at least $3$ vertices has the property that $\frac 14\rho(T)^2+1<\Delta(T)\le \rho(T)^2$, where $\Delta(T)$ is the maximum degree of $T$. Let $\mathbb{P}$ denote the set of spectral radii of all non-trivial trees. In this article, we study the inverse problem that for any $\alpha\in \mathbb{P}$ and integer $r$ satisfying the condition $\frac 14\alpha^2+1<r\le \alpha^2$, is there a tree $T$ such that $\Delta(T)=r$ and $\rho(T)=\alpha$? For any positive integer $r$ and positive number $\alpha$, let ${\mathscr W}_r(\alpha)$ denote a set of non-negative real numbers defined as follows: $\alpha\in {\mathscr W}_r(\alpha)$, and for any multi-set $\{q_i\in {\mathscr W}_r(\alpha): q_i>0, 1\le i\le s\}$, if $\beta:=\alpha-\sum\limits_{i=1}^sq_i^{-1}\ge 0$ and $s\le r-\left \lceil \frac{\beta}{\beta+1}\right\rceil$, then $\beta \in {\mathscr W}_r(\alpha)$. We first show that $0\in {\mathscr W}_r(\alpha)$ if and only if there exists a tree $T$ with $\Delta(T)\le r$ and $\rho(T)=\alpha$. It follows directly that $\mathbb{P}$ is exactly the set of positive numbers $\alpha$ such that $0\in {\mathscr W}_{\lfloor\alpha^2\rfloor}(\alpha)$. Applying this conclusion, we prove that for any two positive integers $r\ge 2$ and $k$, there exists a tree $T$ with $\Delta(T)=r$ and $\rho(T)=\sqrt k$ if and only if $\frac 14 k+1<r\le k$.