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2. Ordering the non-starlike trees with large reverse Wiener indices
- Creator:
- Li, Shuxian and Zhou, Bo
- Format:
- bez média and svazek
- Type:
- model:article and TEXT
- Subject:
- distance, diameter, Wiener index, reverse Wiener index, trees, starlike trees;, and caterpillars
- Language:
- English
- Description:
- The reverse Wiener index of a connected graph $G$ is defined as \[ \Lambda (G)=\frac {1}{2}n(n-1)d-W(G), \] where $n$ is the number of vertices, $d$ is the diameter, and $W(G)$ is the Wiener index (the sum of distances between all unordered pairs of vertices) of $G$. We determine the $n$-vertex non-starlike trees with the first four largest reverse Wiener indices for $n\ge 8$, and the $n$-vertex non-starlike non-caterpillar trees with the first four largest reverse Wiener indices for $n\ge 10$.
- Rights:
- http://creativecommons.org/publicdomain/mark/1.0/ and policy:public
3. Remarks on spectral radius and Laplacian eigenvalues of a graph
- Creator:
- Zhou, Bo and Cho, Han Hyuk
- Format:
- bez média and svazek
- Type:
- model:article and TEXT
- Subject:
- spectral radius, Laplacian eigenvalue, and strongly regular graph
- Language:
- English
- Description:
- Let $G$ be a graph with $n$ vertices, $m$ edges and a vertex degree sequence $(d_1, d_2, \dots , d_n)$, where $d_1 \ge d_2 \ge \dots \ge d_n$. The spectral radius and the largest Laplacian eigenvalue are denoted by $\rho (G)$ and $\mu (G)$, respectively. We determine the graphs with \[ \rho (G) = \frac{d_n - 1}{2} + \sqrt{2m - nd_n + \frac{(d_n +1)^2}{4}} \] and the graphs with $d_n\ge 1$ and \[ \mu (G) = d_n + \frac{1}{2} + \sqrt {\sum _{i=1}^n d_i (d_i-d_n) + \Bigl (d_n - \frac{1}{2} \Bigr )^2}. \] We also present some sharp lower bounds for the Laplacian eigenvalues of a connected graph.
- Rights:
- http://creativecommons.org/publicdomain/mark/1.0/ and policy:public