Line and Plane Cover Numbers Revisited

TL;DR

This paper investigates the computational complexity of covering vertices of graphs with lines and planes in 2D and 3D, revealing NP-hardness results and exact values for specific graph classes.

Contribution

It proves NP-hardness of deciding if a planar graph's 2D line cover number is 2 and characterizes the universal stacked triangulation's cover number, advancing understanding of geometric graph covering.

Findings

NP-hardness of deciding D line cover number for planar graphs

Universal stacked triangulation has D line cover number equal to depth+1

Graphs with 2 plane cover number have at most 5n-19 edges

Abstract

A measure for the visual complexity of a straight-line crossing-free drawing of a graph is the minimum number of lines needed to cover all vertices. For a given graph $G$, the minimum such number (over all drawings in dimension $d \in \{2,3\}$) is called the \emph{$d$-dimensional weak line cover number} and denoted by $\pi^1_d(G)$. In 3D, the minimum number of \emph{planes} needed to cover all vertices of~$G$ is denoted by $\pi^2_3(G)$. When edges are also required to be covered, the corresponding numbers $\rho^1_d(G)$ and $\rho^2_3(G)$ are called the \emph{(strong) line cover number} and the \emph{(strong) plane cover number}. Computing any of these cover numbers -- except $\pi^1_2(G)$ -- is known to be NP-hard. The complexity of computing $\pi^1_2(G)$ was posed as an open problem by Chaplick et al. [WADS 2017]. We show that it is NP-hard to decide, for a given planar graph~$G$, whether $\pi^1_2(G)=2$. We further show that the universal stacked triangulation of depth~$d$, $G_d$, has $\pi^1_2(G_d)=d+1$. Concerning~3D, we show that any $n$-vertex graph~$G$ with $\rho^2_3(G)=2$ has at most $5n-19$ edges, which is tight.