Efficient Generation of One-Factorizations through Hill Climbing
Abstract
It is well known that for every even integer , the complete graph has a one-factorization, namely a proper edge coloring with colors. Unfortunately, not much is known about the possible structure of large one-factorizations. Also, at present we have only woefully few explicit constructions of one-factorizations. Specifically, we know essentially nothing about the {\em typical} properties of one-factorizations for large . Suppose that is a graph whose vertex set includes the set of all order- one-factorizations and that takes its minimum precisely at the one-factorizations. Given and , we can generate one-factorizations via hill climbing. Namely, by taking a walk on that tends to go from a vertex to a neighbor of smaller . For over 30 years, hill-climbing has been essentially the only method for generating many large one-factorizations. However, the validity of such methods was supported so far only by numerical evidence. Here, we present for the first time hill-climbing algorithms that provably generate an order- one-factorization in steps regardless of the starting state, while all vertex degrees in the underlying graph are appropriately bounded. We also raise many questions and conjectures regarding hill-climbing methods and concerning the possible and typical structure of one-factorizations.
Cite
@article{arxiv.1707.00477,
title = {Efficient Generation of One-Factorizations through Hill Climbing},
author = {Maya Dotan and Nati Linial},
journal= {arXiv preprint arXiv:1707.00477},
year = {2017}
}