Boland, Natashia; Kalinowski, Thomas; Kaur, Simranjit

Author(s)

Boland, Natashia

Kalinowski, Thomas

Kaur, Simranjit

Publication Date

2015-12

Abstract

We consider a problem that marries network flows and scheduling, motivated by the need to schedule maintenance activities in infrastructure networks, such as rail or general logistics networks. Network elements must undergo regular preventive maintenance, shutting down the arc for the duration of the activity. Careful coordination of these arc maintenance jobs can dramatically reduce the impact of such shutdown jobs on the flow carried by the network. Scheduling such jobs between given release dates and deadlines so as to maximize the total flow over time presents an intriguing case to study the role of time discretization. Here we prove that if the problem data is integer, and no flow can be stored at nodes, we can restrict attention to integer job start times. However if flow can be stored, fractional start times may be needed. This makes traditional strong integer programming scheduling models difficult to apply. Here we formulate an exact integer programming model for the continuous time problem, as well as integer programming models based on time discretization that can provide dual bounds, and that can – with minor modifications – also yield primal bounds. The resulting bounds are demonstrated to have small gaps on test instances, and offer a good trade-off for bound quality against computing time.

Citation

Computers & Operations Research, v.64, p. 113-129

ISSN

1873-765X

0305-0548

Link

https://hdl.handle.net/1959.11/26782

Publisher

Pergamon Press

Title

Scheduling network maintenance jobs with release dates and deadlines to maximize total flow over time: Boundsand solution strategies

Type of document

Journal Article

Entity Type

Publication

Author(s)	Boland, Natashia Kalinowski, Thomas Kaur, Simranjit
Publication Date	2015-12
Abstract	We consider a problem that marries network flows and scheduling, motivated by the need to schedule maintenance activities in infrastructure networks, such as rail or general logistics networks. Network elements must undergo regular preventive maintenance, shutting down the arc for the duration of the activity. Careful coordination of these arc maintenance jobs can dramatically reduce the impact of such shutdown jobs on the flow carried by the network. Scheduling such jobs between given release dates and deadlines so as to maximize the total flow over time presents an intriguing case to study the role of time discretization. Here we prove that if the problem data is integer, and no flow can be stored at nodes, we can restrict attention to integer job start times. However if flow can be stored, fractional start times may be needed. This makes traditional strong integer programming scheduling models difficult to apply. Here we formulate an exact integer programming model for the continuous time problem, as well as integer programming models based on time discretization that can provide dual bounds, and that can – with minor modifications – also yield primal bounds. The resulting bounds are demonstrated to have small gaps on test instances, and offer a good trade-off for bound quality against computing time.
Citation	Computers & Operations Research, v.64, p. 113-129
ISSN	1873-765X 0305-0548
Link	https://hdl.handle.net/1959.11/26782
Publisher	Pergamon Press
Title	Scheduling network maintenance jobs with release dates and deadlines to maximize total flow over time: Boundsand solution strategies
Type of document	Journal Article
Entity Type	Publication

Scheduling network maintenance jobs with release dates and deadlines to maximize total flow over time: Boundsand solution strategies

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