The valve location problem in simple network topologies.

H.L. Bodlaender; A. Grigoriev; N.V. Grigorieva; A. Hendriks

doi:10.1287/ijoc.1090.0365

The valve location problem in simple network topologies.

H.L. Bodlaender^*, A. Grigoriev, N.V. Grigorieva, A. Hendriks

^*Corresponding author for this work

Quantitative Economics

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

To control possible spills in liquid or gas transporting pipe systems, the systems are usually equipped with shutoff valves. In case of an accidental leak, these valves separate the system into a number of pieces, limiting the spill effect. In this paper, we consider the problem, for a given edge-weighted network representing a pipe system and for a given number of valves, of placing the valves in the network in such a way that the maximum possible spill, i.e., the maximum total weight of a piece, is minimized. We show that the problem is NP-hard even if restricted to any of the following settings: (i) series-parallel graphs, and hence graphs of treewidth two; and (ii) all edge weights equal one. If the network is a simple path, a cycle, or a tree, the problem can be solved in polynomial time. We also give a pseudopolynomial-time algorithm and a fully polynomial-time approximation scheme for networks of bounded treewidth.

Original language	English
Pages (from-to)	433-442
Number of pages	10
Journal	Informs Journal on Computing
Volume	22
Issue number	3
DOIs	https://doi.org/10.1287/ijoc.1090.0365
Publication status	Published - 1 Jan 2010

Keywords

valve location problem
computational complexity
bounded treewidth
dynamic programming
binary search
TREEWIDTH
GRAPHS

Access to Document

10.1287/ijoc.1090.0365

Cite this

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title = "The valve location problem in simple network topologies.",

abstract = "To control possible spills in liquid or gas transporting pipe systems, the systems are usually equipped with shutoff valves. In case of an accidental leak, these valves separate the system into a number of pieces, limiting the spill effect. In this paper, we consider the problem, for a given edge-weighted network representing a pipe system and for a given number of valves, of placing the valves in the network in such a way that the maximum possible spill, i.e., the maximum total weight of a piece, is minimized. We show that the problem is NP-hard even if restricted to any of the following settings: (i) series-parallel graphs, and hence graphs of treewidth two; and (ii) all edge weights equal one. If the network is a simple path, a cycle, or a tree, the problem can be solved in polynomial time. We also give a pseudopolynomial-time algorithm and a fully polynomial-time approximation scheme for networks of bounded treewidth.",

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AU - Bodlaender, H.L.

AU - Grigoriev, A.

AU - Grigorieva, N.V.

AU - Hendriks, A.

PY - 2010/1/1

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N2 - To control possible spills in liquid or gas transporting pipe systems, the systems are usually equipped with shutoff valves. In case of an accidental leak, these valves separate the system into a number of pieces, limiting the spill effect. In this paper, we consider the problem, for a given edge-weighted network representing a pipe system and for a given number of valves, of placing the valves in the network in such a way that the maximum possible spill, i.e., the maximum total weight of a piece, is minimized. We show that the problem is NP-hard even if restricted to any of the following settings: (i) series-parallel graphs, and hence graphs of treewidth two; and (ii) all edge weights equal one. If the network is a simple path, a cycle, or a tree, the problem can be solved in polynomial time. We also give a pseudopolynomial-time algorithm and a fully polynomial-time approximation scheme for networks of bounded treewidth.

AB - To control possible spills in liquid or gas transporting pipe systems, the systems are usually equipped with shutoff valves. In case of an accidental leak, these valves separate the system into a number of pieces, limiting the spill effect. In this paper, we consider the problem, for a given edge-weighted network representing a pipe system and for a given number of valves, of placing the valves in the network in such a way that the maximum possible spill, i.e., the maximum total weight of a piece, is minimized. We show that the problem is NP-hard even if restricted to any of the following settings: (i) series-parallel graphs, and hence graphs of treewidth two; and (ii) all edge weights equal one. If the network is a simple path, a cycle, or a tree, the problem can be solved in polynomial time. We also give a pseudopolynomial-time algorithm and a fully polynomial-time approximation scheme for networks of bounded treewidth.

KW - valve location problem

KW - computational complexity

KW - bounded treewidth

KW - dynamic programming

KW - binary search

KW - TREEWIDTH

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