For a given number of colours, $s$, the guessing number of a graph is the base $s$ logarithm of the size of the largest family of colourings of the vertex set of the graph such that the colour of each vertex can be determined from the colours of the vertices in its neighbourhood. An upper bound for the guessing number of the $n$-vertex cycle graph $C_n$ is $n/2$. It is known that the guessing number equals $n/2$ whenever $n$ is even or $s$ is a perfect square. We show that, for any given integer $s \geq 2$, if $a$ is the largest factor of $s$ less than or equal to $\sqrt{s}$, for sufficiently large odd $n$, the guessing number of $C_n$ with $s$ colours is $(n-1)/2 + \log_s(a)$. This answers a question posed by Christofides and Markström in 2011.We also present an explicit protocol which achieves this bound for every $n$. Linking this to index coding with side information, we deduce that the information defect of $C_n$ with $s$ colours is $(n+1)/2 - \log_s(a)$ for sufficiently large odd $n$.
@article{10_37236_5964,
author = {Ross Atkins and Puck Rombach and Fiona Skerman},
title = {Guessing numbers of odd cycles},
journal = {The electronic journal of combinatorics},
year = {2017},
volume = {24},
number = {1},
doi = {10.37236/5964},
zbl = {1358.05092},
url = {http://geodesic.mathdoc.fr/articles/10.37236/5964/}
}
TY - JOUR
AU - Ross Atkins
AU - Puck Rombach
AU - Fiona Skerman
TI - Guessing numbers of odd cycles
JO - The electronic journal of combinatorics
PY - 2017
VL - 24
IS - 1
UR - http://geodesic.mathdoc.fr/articles/10.37236/5964/
DO - 10.37236/5964
ID - 10_37236_5964
ER -
%0 Journal Article
%A Ross Atkins
%A Puck Rombach
%A Fiona Skerman
%T Guessing numbers of odd cycles
%J The electronic journal of combinatorics
%D 2017
%V 24
%N 1
%U http://geodesic.mathdoc.fr/articles/10.37236/5964/
%R 10.37236/5964
%F 10_37236_5964
Ross Atkins; Puck Rombach; Fiona Skerman. Guessing numbers of odd cycles. The electronic journal of combinatorics, Tome 24 (2017) no. 1. doi: 10.37236/5964
