6533b7d0fe1ef96bd125b9a6

RESEARCH PRODUCT

On List Coloring with Separation of the Complete Graph and Set System Intersections

Olivier TogniJean-christophe GodinRémi Grisot

subject

[MATH.MATH-CO] Mathematics [math]/Combinatorics [math.CO]FOS: Computer and information sciences[INFO.INFO-DM] Computer Science [cs]/Discrete Mathematics [cs.DM]05C15 05C25Discrete Mathematics (cs.DM)FOS: MathematicsMathematics - CombinatoricsCombinatorics (math.CO)Computer Science - Discrete Mathematics

description

We consider the following list coloring with separation problem: Given a graph $G$ and integers $a,b$, find the largest integer $c$ such that for any list assignment $L$ of $G$ with $|L(v)|= a$ for any vertex $v$ and $|L(u)\cap L(v)|\le c$ for any edge $uv$ of $G$, there exists an assignment $\varphi$ of sets of integers to the vertices of $G$ such that $\varphi(u)\subset L(u)$ and $|\varphi(v)|=b$ for any vertex $u$ and $\varphi(u)\cap \varphi(v)=\emptyset$ for any edge $uv$. Such a value of $c$ is called the separation number of $(G,a,b)$. Using a special partition of a set of lists for which we obtain an improved version of Poincar\'e's crible, we determine the separation number of the complete graph $K_n$ for some values of $a,b$ and $n$, and prove bounds for the remaining values.

yearjournalcountryeditionlanguage
2022-09-07
http://arxiv.org/abs/2209.03436