Structurally Parameterized d-Scattered Set

Katsikarelis, Ioannis; Lampis, Michael; Paschos, Vangélis Th.

doi:10.1007/978-3-030-00256-5_24

Cited by 16 publications

(11 citation statements)

References 32 publications

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“…Before we proceed further in the description of our reduction, let us give the basic ideas, which look like other SETH-based lower bounds from the literature [17,[20][21][22]24]. The constructed graph consists of a main part of n paths of length 4m, each divided into m sections.…”

Section: Lower Boundmentioning

confidence: 99%

Upper Dominating Set: Tight Algorithms for Pathwidth and Sub-Exponential Approximation

Dublois¹,

Lampis²,

Paschos³

2021

Preprint

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An upper dominating set is a minimal dominating set in a graph. In the Upper Dominating Set problem, the goal is to find an upper dominating set of maximum size. We study the complexity of parameterized algorithms for Upper Dominating Set, as well as its sub-exponential approximation. First, we prove that, under ETH, k-Upper Dominating Set cannot be solved in time)), and in the same time we show under the same complexity assumption that for any constant ratio r and any ε > 0, there is no r-approximation algorithm running in time O(n k 1−ε ). Then, we settle the problem's complexity parameterized by pathwidth by giving an algorithm running in time O * (6 pw ) (improving the current best O * (7 pw )), and a lower bound showing that our algorithm is the best we can get under the SETH. Furthermore, we obtain a simple sub-exponential approximation algorithm for this problem: an algorithm that produces an r-approximation in time n O(n/r) , for any desired approximation ratio r < n. We finally show that this time-approximation trade-off is tight, up to an arbitrarily small constant in the second exponent: under the randomized ETH, and for any ratio r > 1 and ε > 0, no algorithm can output an r-approximation in time n (n/r) 1−ε . Hence, we completely characterize the approximability of the problem in sub-exponential time.

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Section: Lower Boundmentioning

confidence: 99%

Upper Dominating Set: Tight Algorithms for Pathwidth and Sub-Exponential Approximation

Dublois¹,

Lampis²,

Paschos³

2021

Preprint

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“…It is also worth noting here that INDEPENDENT SET problem can be generalized to the d-SCATTERED SET problem where we are given an (edge-weighted) graph and are asked to select at least k vertices, so that the distance between any pair is at least d [92]. Recently in [93] some lower and upper bounds on the approximation of the d-SCATTERED SET problem have been provided.…”

Section: Theorem 10 ([8]mentioning

confidence: 99%

A Survey on Approximation in Parameterized Complexity: Hardness and Algorithms

et al. 2020

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“…Furthermore, [14] shows the problem admits an EPTAS on (apex)-minor-free graphs, based on the theory of bidimensionality, while on a related result [22] offers an n O( √ n) -time algorithm for planar graphs, making use of Voronoi diagrams and based on ideas previously used to obtain geometric QPTASs. Finally, [21] presents tight upper/lower bounds on the structurally parameterized complexity of the problem, while [24] shows that it admits an almost linear kernel on every nowhere dense graph class.…”

Section: Inapproximability Approximationmentioning

confidence: 99%

“…The problem has been well-studied, also from the parameterized point of view [21,24], while approximability in polynomial time has already been considered for bipartite, regular and degree-bounded graphs [12,11], perhaps the natural candidate for the next intractability frontier. This paper aims to advance our understanding in this direction by providing the first lower bound on the approximation ratio of any polynomial-time algorithm as a function of the maximum degree of any vertex in the input graph, while also improving upon the known ratios to match this lower bound.…”

Section: Introductionmentioning

confidence: 99%

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

Katsikarelis¹,

Lampis²,

Paschos³

2020

Approximation and Online Algorithms

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In the d-Scattered Set 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 Independent Set, of which the problem is a generalization. Specifically, we show:• A lower bound of ∆ d/2 − on the approximation ratio of any polynomial-time algorithm for graphs of maximum degree ∆ and an improved upper bound of O(∆ d/2 ) on the approximation ratio of any greedy scheme for this problem.• A polynomial-time 2 √ 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 ρ-approximation algorithm of (roughly) 2 n 1− ρd for even d and 2 n 1− ρ(d+ρ) for odd d (under the randomized ETH), complemented by ρ-approximation algorithms of running times that (almost) match these bounds.

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Structurally Parameterized d-Scattered Set

Cited by 16 publications

References 32 publications

Upper Dominating Set: Tight Algorithms for Pathwidth and Sub-Exponential Approximation

Upper Dominating Set: Tight Algorithms for Pathwidth and Sub-Exponential Approximation

A Survey on Approximation in Parameterized Complexity: Hardness and Algorithms

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

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