Lower Bounds for the Graph Homomorphism Problem
Abstract
The graph homomorphism problem (HOM) asks whether the vertices of a given -vertex graph can be mapped to the vertices of a given -vertex graph such that each edge of is mapped to an edge of . The problem generalizes the graph coloring problem and at the same time can be viewed as a special case of the -CSP problem. In this paper, we prove several lower bound for HOM under the Exponential Time Hypothesis (ETH) assumption. The main result is a lower bound . This rules out the existence of a single-exponential algorithm and shows that the trivial upper bound is almost asymptotically tight. We also investigate what properties of graphs and make it difficult to solve HOM. An easy observation is that an upper bound can be improved to where is the minimum size of a vertex cover of . The second lower bound shows that the upper bound is asymptotically tight. As to the properties of the "right-hand side" graph , it is known that HOM can be solved in time and where is the maximum degree of and is the treewidth of . This gives single-exponential algorithms for graphs of bounded maximum degree or bounded treewidth. Since the chromatic number does not exceed and , it is natural to ask whether similar upper bounds with respect to can be obtained. We provide a negative answer to this question by establishing a lower bound for any function . We also observe that similar lower bounds can be obtained for locally injective homomorphisms.
Cite
@article{arxiv.1502.05447,
title = {Lower Bounds for the Graph Homomorphism Problem},
author = {Fedor V. Fomin and Alexander Golovnev and Alexander S. Kulikov and Ivan Mihajlin},
journal= {arXiv preprint arXiv:1502.05447},
year = {2015}
}
Comments
19 pages