Improved (In-)Approximability Bounds for d-Scattered Set

In the $d$-${\rm S{\small CATTERED}\;S{\small ET}}$ problem we are asked to select at least $k$ vertices of a given graph, so that the distance between any pair is at least $d$. We study the problem's (in-)approximability and offer improvements and extensions of known results for ${\rm I{\small...

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Bibliographic Details
Published in:Journal of graph algorithms and applications 2023, Vol.27 (3), p.219-238
Main Authors: Katsikarelis, Ioannis, Lampis, Michael, Paschos, Vangelis
Format: Article
Language:English
Subjects:
Computer Science
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Summary:In the $d$-${\rm S{\small CATTERED}\;S{\small ET}}$ problem we are asked to select at least $k$ vertices of a given graph, so that the distance between any pair is at least $d$. We study the problem's (in-)approximability and offer improvements and extensions of known results for ${\rm I{\small NDEPENDENT}\;S{\small ET}}$, of which it is a generalization. Specifically, we show: A lower bound of $\Delta^{\lfloor d/2\rfloor-\epsilon}$ on the approximation ratio of any polynomial-time algorithm for graphs of maximum degree $\Delta$ and an improved upper bound of $O(\Delta^{\lfloor d/2\rfloor})$ on the approximation ratio of any greedy scheme for this problem. A polynomial-time $2\sqrt{n}$-approximation for bipartite graphs and even values of $d$, that matches the known lower bound by considering the only remaining case. A lower bound on the complexity of any $\rho$-approximation algorithm of (roughly) $2^{\frac{n^{1-\epsilon}}{\rho d}}$ for even $d$ and $2^{\frac{n^{1-\epsilon}}{\rho(d+\rho)}}$ for odd $d$ (under the randomized ETH), complemented by $\rho$-approximation algorithms of running-times that (almost) match these bounds.
ISSN:1526-1719
1526-1719
DOI:10.7155/jgaa.00621