Parameterized Complexity of Bandwidth on Trees
Abstract
The bandwidth of a -vertex graph is the smallest integer such that there exists a bijective function , called a layout of , such that for every edge , . In the {\sc Bandwidth} problem we are given as input a graph and integer , and asked whether the bandwidth of is at most . We present two results concerning the parameterized complexity of the {\sc Bandwidth} problem on trees. First we show that an algorithm for {\sc Bandwidth} with running time would violate the Exponential Time Hypothesis, even if the input graphs are restricted to be trees of pathwidth at most two. Our lower bound shows that the classical time algorithm by Saxe [SIAM Journal on Algebraic and Discrete Methods, 1980] is essentially optimal. Our second result is a polynomial time algorithm that given a tree and integer , either correctly concludes that the bandwidth of is more than or finds a layout of of bandwidth at most . This is the first parameterized approximation algorithm for the bandwidth of trees.
Cite
@article{arxiv.1404.7810,
title = {Parameterized Complexity of Bandwidth on Trees},
author = {Markus Sortland Dregi and Daniel Lokshtanov},
journal= {arXiv preprint arXiv:1404.7810},
year = {2014}
}
Comments
33 pages, To appear at ICALP 2014