# A characterization of distance matrices of weighted cubic graphs and   Peterson graphs

**Authors:** Elena Rubei, Dario Villanis Ziani

arXiv: 1901.00360 · 2020-03-02

## TL;DR

This paper characterizes the distance matrices of positive-weighted hypercube and Petersen graphs, providing insights into their structure and distinguishing features within weighted graph theory.

## Contribution

It offers new characterizations of distance matrices for weighted hypercube and Petersen graphs, expanding understanding of their structural properties.

## Key findings

- Characterization of distance matrices of weighted hypercube graphs
- Distinction between bipartite n-regular graphs and hypercube graphs
- Characterization of distance matrices of weighted Petersen graphs

## Abstract

Given a positive-weighted simple connected graph with $m$ vertices, labelled by the numbers $1,\ldots,m$, we can construct an $m \times m$ matrix whose entry $(i,j)$, for any $i,j\in\{1,\dots,m\}$, is the minimal weight of a path between $i$ and $j$, where the weight of a path is the sum of the weights of its edges. Such a matrix is called the distance matrix of the weighted graph. There is wide literature about distance matrices of weighted graphs. In this paper we characterize distance matrices of positive-weighted $n$-hypercube graphs. Moreover we show that a connected bipartite $n$-regular graph with order $2^n$ is not necessarily the $n$-hypercube graph. Finally we give a characterization of distance matrices of positive-weighted Petersen graphs.

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Source: https://tomesphere.com/paper/1901.00360