Vertex colouring edge weightings: a logarithmic upper bound on weight-choosability
The electronic journal of combinatorics, Tome 28 (2021) no. 2
A graph $G$ is said to be $(k,m)$-choosable if for any assignment of $k$-element lists $L_v \subset \mathbb{R}$ to the vertices $v \in V(G)$ and any assignment of $m$-element lists $L_e \subset \mathbb{R}$ to the edges $e \in E(G)$ there exists a total weighting $w: V(G) \cup E(G) \rightarrow \mathbb{R}$ of $G$ such that $w(v) \in L_v$ for any vertex $v \in V(G)$ and $w(e) \in L_e$ for any edge $e \in E(G)$ and furthermore, such that for any pair of adjacent vertices $u,v$, we have $w(u)+ \sum_{e \in E(u)}w(e) \neq w(v)+ \sum_{e \in E(v)}w(e)$, where $E(u)$ and $E(v)$ denote the edges incident to $u$ and $v$ respectively. In this paper we give an algorithmic proof showing that any graph $G$ without isolated edges is $(1, 2 \lceil \log_2(\Delta(G)) \rceil+1)$-choosable, where $\Delta(G)$ denotes the maximum degree in $G$.
DOI :
10.37236/6878
Classification :
05C15, 05C07
Mots-clés : \((k,m)\)-choosable graph, total weighting
Mots-clés : \((k,m)\)-choosable graph, total weighting
@article{10_37236_6878,
author = {Kasper Szabo Lyngsie and Liang Zhong},
title = {Vertex colouring edge weightings: a logarithmic upper bound on weight-choosability},
journal = {The electronic journal of combinatorics},
year = {2021},
volume = {28},
number = {2},
doi = {10.37236/6878},
zbl = {1464.05156},
url = {http://geodesic.mathdoc.fr/articles/10.37236/6878/}
}
TY - JOUR AU - Kasper Szabo Lyngsie AU - Liang Zhong TI - Vertex colouring edge weightings: a logarithmic upper bound on weight-choosability JO - The electronic journal of combinatorics PY - 2021 VL - 28 IS - 2 UR - http://geodesic.mathdoc.fr/articles/10.37236/6878/ DO - 10.37236/6878 ID - 10_37236_6878 ER -
Kasper Szabo Lyngsie; Liang Zhong. Vertex colouring edge weightings: a logarithmic upper bound on weight-choosability. The electronic journal of combinatorics, Tome 28 (2021) no. 2. doi: 10.37236/6878
Cité par Sources :