Alternative parameterizations of Metric Dimension

TL;DR

This paper explores the parameterized complexity of the Metric Dimension problem, introducing new kernelization results and algorithms for the dual parameterization, and analyzing kernelization limits with respect to vertex cover number.

Contribution

It provides a polynomial kernel and an FPT algorithm for the dual parameterization of Metric Dimension, and shows kernelization impossibility when parameterized by vertex cover plus solution size.

Findings

A kernel with at most 3k^4 vertices for the dual parameterization.

An algorithm with runtime O^*(4^{k+o(k)}) for the dual parameterization.

No polynomial kernel exists when parameterized by vertex cover number plus solution size.

Abstract

A set of vertices $W$ in a graph $G$ is called resolving if for any two distinct $x,y\in V(G)$, there is $v\in W$ such that ${\rm dist}_G(v,x)\neq{\rm dist}_G(v,y)$, where ${\rm dist}_G(u,v)$ denotes the length of a shortest path between $u$ and $v$ in the graph $G$. The metric dimension ${\rm md}(G)$ of $G$ is the minimum cardinality of a resolving set. The Metric Dimension problem, i.e. deciding whether ${\rm md}(G)\le k$, is NP-complete even for interval graphs (Foucaud et al., 2017). We study Metric Dimension (for arbitrary graphs) from the lens of parameterized complexity. The problem parameterized by $k$ was proved to be $W[2]$-hard by Hartung and Nichterlein (2013) and we study the dual parameterization, i.e., the problem of whether ${\rm md}(G)\le n- k,$ where $n$ is the order of $G$. We prove that the dual parameterization admits (a) a kernel with at most $3k^4$ vertices and (b) an algorithm of runtime $O^*(4^{k+o(k)}).$ Hartung and Nichterlein (2013) also observed that Metric Dimension is fixed-parameter tractable when parameterized by the vertex cover number $vc(G)$ of the input graph. We complement this observation by showing that it does not admit a polynomial kernel even when parameterized by $vc(G) + k$. Our reduction also gives evidence for non-existence of polynomial Turing kernels.