The vertex leafage of chordal graphs

TL;DR

This paper investigates the vertex leafage parameter of chordal graphs, establishing its computational complexity, algorithms for specific cases, and the existence of models that realize both leafage and vertex leafage.

Contribution

It proves NP-completeness of determining vertex leafage for fixed k, provides algorithms for graphs with bounded leafage, and shows models realizing both leafage and vertex leafage.

Findings

NP-completeness for fixed k when deciding vertex leafage

Polynomial-time algorithm for graphs with bounded leafage

Existence of models realizing both leafage and vertex leafage

Abstract

Every chordal graph $G$ can be represented as the intersection graph of a collection of subtrees of a host tree, a so-called {\em tree model} of $G$. The leafage $\ell(G)$ of a connected chordal graph $G$ is the minimum number of leaves of the host tree of a tree model of $G$. The vertex leafage $\vl(G)$ is the smallest number $k$ such that there exists a tree model of $G$ in which every subtree has at most $k$ leaves. The leafage is a polynomially computable parameter by the result of \cite{esa}. In this contribution, we study the vertex leafage. We prove for every fixed $k\geq 3$ that deciding whether the vertex leafage of a given chordal graph is at most $k$ is NP-complete by proving a stronger result, namely that the problem is NP-complete on split graphs with vertex leafage of at most $k+1$. On the other hand, for chordal graphs of leafage at most $\ell$, we show that the vertex leafage can be calculated in time $n^{O(\ell)}$. Finally, we prove that there exists a tree model that realizes both the leafage and the vertex leafage of $G$. Notably, for every path graph $G$, there exists a path model with $\ell(G)$ leaves in the host tree and it can be computed in $O(n^3)$ time.