A theorem on the approximation of set cover and vertex cover

International audience An $f(n)$ $\textit{dominance bound}$ on a heuristic for some problem is a guarantee that the heuristic always returns a solution not worse than at least $f(n)$ solutions. In this paper, we analyze several heuristics for $\textit{Vertex Cover}$, $\textit{Set Cover}$, and $\textit{Knapsack}$ for dominance bounds. In particular, we show that the well-known $\textit{maximal matching}$ heuristic of $\textit{Vertex Cover}$ provides an excellent dominance bound. We introduce new general analysis techniques which apply to a wide range of problems and heuristics for this measure. Certain general results relating approximation ratio and combinatorial dominance guarantees for optimization problems over subsets are established. We prove certain limitations on the combinatorial dominance guarantees of polynomial-time approximation schemes (PTAS), and give inapproximability results for the problems above.

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Complexity of the Maximum k-Path Vertex Cover Problem

IEICE Transactions on Fundamentals of Electronics Communications and Computer Sciences ◽

10.1587/transfun.2019dmp0014 ◽

2020 ◽

Vol E103.A (10) ◽

pp. 1193-1201

Author(s):

Eiji MIYANO ◽

Toshiki SAITOH ◽

Ryuhei UEHARA ◽

Tsuyoshi YAGITA ◽

Tom C. van der ZANDEN

Keyword(s):

Vertex Cover ◽

Vertex Cover Problem ◽

Cover Problem

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Approximation algorithm for minimum connected 3-path vertex cover

Discrete Applied Mathematics ◽

10.1016/j.dam.2020.08.008 ◽

2020 ◽

Vol 287 ◽

pp. 77-84

Author(s):

Pengcheng Liu ◽

Zhao Zhang ◽

Xianyue Li ◽

Weili Wu

Keyword(s):

Approximation Algorithm ◽

Vertex Cover

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PTAS for minimum weighted connected vertex cover problem with c-local condition in unit disk graphs

Journal of Combinatorial Optimization ◽

10.1007/s10878-010-9315-9 ◽

2010 ◽

Vol 22 (4) ◽

pp. 663-673 ◽

Cited By ~ 3

Author(s):

Lidan Fan ◽

Zhao Zhang ◽

Wei Wang

Keyword(s):

Unit Disk ◽

Vertex Cover ◽

Local Condition ◽

Unit Disk Graphs ◽

Vertex Cover Problem ◽

Connected Vertex Cover ◽

Cover Problem ◽

Connected Vertex

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From the Quasi-Total Strong Differential to Quasi-Total Italian Domination in Graphs

Symmetry ◽

10.3390/sym13061036 ◽

2021 ◽

Vol 13 (6) ◽

pp. 1036

Author(s):

Abel Cabrera Martínez ◽

Alejandro Estrada-Moreno ◽

Juan Alberto Rodríguez-Velázquez

Keyword(s):

Vertex Cover ◽

Domination Number ◽

Theoretical Computer Science ◽

Discrete Mathematics ◽

Special Issue ◽

Total Domination Number ◽

Theoretical Computer ◽

Graph Parameters ◽

Semitotal Domination ◽

Domination In Graphs

This paper is devoted to the study of the quasi-total strong differential of a graph, and it is a contribution to the Special Issue “Theoretical computer science and discrete mathematics” of Symmetry. Given a vertex x∈V(G) of a graph G, the neighbourhood of x is denoted by N(x). The neighbourhood of a set X⊆V(G) is defined to be N(X)=⋃x∈XN(x), while the external neighbourhood of X is defined to be Ne(X)=N(X)∖X. Now, for every set X⊆V(G) and every vertex x∈X, the external private neighbourhood of x with respect to X is defined as the set Pe(x,X)={y∈V(G)∖X:N(y)∩X={x}}. Let Xw={x∈X:Pe(x,X)≠⌀}. The strong differential of X is defined to be ∂s(X)=|Ne(X)|−|Xw|, while the quasi-total strong differential of G is defined to be ∂s*(G)=max{∂s(X):X⊆V(G)andXw⊆N(X)}. We show that the quasi-total strong differential is closely related to several graph parameters, including the domination number, the total domination number, the 2-domination number, the vertex cover number, the semitotal domination number, the strong differential, and the quasi-total Italian domination number. As a consequence of the study, we show that the problem of finding the quasi-total strong differential of a graph is NP-hard.

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