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On approximate data reduction for the Rural Postman Problem: Theory and experiments. / van Bevern, René; Fluschnik, Till; Tsidulko, Oxana Yu.

в: Networks, Том 76, № 4, e21985, 01.12.2020, стр. 485-508.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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van Bevern R, Fluschnik T, Tsidulko OY. On approximate data reduction for the Rural Postman Problem: Theory and experiments. Networks. 2020 дек. 1;76(4):485-508. e21985. Epub 2020 окт. 6. doi: 10.1002/net.21985

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@article{7c0e0225a9d34166bf51b8147150bd27,
title = "On approximate data reduction for the Rural Postman Problem: Theory and experiments",
abstract = "Given an undirected graph with edge weights and a subset R of its edges, the Rural Postman Problem (RPP) is to find a closed walk of minimum total weight containing all edges of R. We prove that RPP is WK[1]-complete parameterized by the number and weight d of edges traversed additionally to the required ones. Thus RPP instances cannot be polynomial-time compressed to instances of size polynomial in d unless the polynomial-time hierarchy collapses. In contrast, denoting by b ≤ 2d the number of vertices incident to an odd number of edges of R and by c ≤ d the number of connected components formed by the edges in R, we show how to reduce any RPP instance I to an RPP instance I′ with 2b + O(c/ϵ) vertices in O(n3) time so that any α-approximate solution for I′ gives an α(1 + ϵ)-approximate solution for I, for any α ≥ 1 and ϵ > 0. That is, we provide a polynomial-size approximate kernelization scheme (PSAKS). We experimentally evaluate it on wide-spread benchmark data sets as well as on two real snow plowing instances from Berlin. We also make first steps toward a PSAKS for the parameter c.",
keywords = "above-guarantee parameterization, capacitated arc routing, Eulerian extension, lossy kernelization, NP-hard problem, parameterized complexity, EULERIAN EXTENSION, ARC, BOUNDS, ALGORITHM",
author = "{van Bevern}, Ren{\'e} and Till Fluschnik and Tsidulko, {Oxana Yu}",
note = "Publisher Copyright: {\textcopyright} 2020 Wiley Periodicals LLC",
year = "2020",
month = dec,
day = "1",
doi = "10.1002/net.21985",
language = "English",
volume = "76",
pages = "485--508",
journal = "Networks",
issn = "0028-3045",
publisher = "Wiley-Liss Inc.",
number = "4",

}

RIS

TY - JOUR

T1 - On approximate data reduction for the Rural Postman Problem: Theory and experiments

AU - van Bevern, René

AU - Fluschnik, Till

AU - Tsidulko, Oxana Yu

N1 - Publisher Copyright: © 2020 Wiley Periodicals LLC

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Given an undirected graph with edge weights and a subset R of its edges, the Rural Postman Problem (RPP) is to find a closed walk of minimum total weight containing all edges of R. We prove that RPP is WK[1]-complete parameterized by the number and weight d of edges traversed additionally to the required ones. Thus RPP instances cannot be polynomial-time compressed to instances of size polynomial in d unless the polynomial-time hierarchy collapses. In contrast, denoting by b ≤ 2d the number of vertices incident to an odd number of edges of R and by c ≤ d the number of connected components formed by the edges in R, we show how to reduce any RPP instance I to an RPP instance I′ with 2b + O(c/ϵ) vertices in O(n3) time so that any α-approximate solution for I′ gives an α(1 + ϵ)-approximate solution for I, for any α ≥ 1 and ϵ > 0. That is, we provide a polynomial-size approximate kernelization scheme (PSAKS). We experimentally evaluate it on wide-spread benchmark data sets as well as on two real snow plowing instances from Berlin. We also make first steps toward a PSAKS for the parameter c.

AB - Given an undirected graph with edge weights and a subset R of its edges, the Rural Postman Problem (RPP) is to find a closed walk of minimum total weight containing all edges of R. We prove that RPP is WK[1]-complete parameterized by the number and weight d of edges traversed additionally to the required ones. Thus RPP instances cannot be polynomial-time compressed to instances of size polynomial in d unless the polynomial-time hierarchy collapses. In contrast, denoting by b ≤ 2d the number of vertices incident to an odd number of edges of R and by c ≤ d the number of connected components formed by the edges in R, we show how to reduce any RPP instance I to an RPP instance I′ with 2b + O(c/ϵ) vertices in O(n3) time so that any α-approximate solution for I′ gives an α(1 + ϵ)-approximate solution for I, for any α ≥ 1 and ϵ > 0. That is, we provide a polynomial-size approximate kernelization scheme (PSAKS). We experimentally evaluate it on wide-spread benchmark data sets as well as on two real snow plowing instances from Berlin. We also make first steps toward a PSAKS for the parameter c.

KW - above-guarantee parameterization

KW - capacitated arc routing

KW - Eulerian extension

KW - lossy kernelization

KW - NP-hard problem

KW - parameterized complexity

KW - EULERIAN EXTENSION

KW - ARC

KW - BOUNDS

KW - ALGORITHM

UR - http://www.scopus.com/inward/record.url?scp=85084978725&partnerID=8YFLogxK

U2 - 10.1002/net.21985

DO - 10.1002/net.21985

M3 - Article

AN - SCOPUS:85084978725

VL - 76

SP - 485

EP - 508

JO - Networks

JF - Networks

SN - 0028-3045

IS - 4

M1 - e21985

ER -

ID: 25606690