Development of rehabilitation plans for water mains replacement considering risk and cost-benefit assessment
Created by W.Langdon from
gp-bibliography.bib Revision:1.8081
- @Article{Giustolisi:2006:CEES,
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author = "Orazio Giustolisi and Daniele Laucelli and
Dragan A. Savic",
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title = "Development of rehabilitation plans for water mains
replacement considering risk and cost-benefit
assessment",
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journal = "Civil Engineering and Environmental Systems",
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year = "2006",
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volume = "23",
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number = "6",
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pages = "175--190",
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note = "Special Issue: Papers selected from the Eighth
International Conference on Computing and Control for
the Water Industry",
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keywords = "genetic algorithms, genetic programming, Pipe burst
modelling, Water mains rehabilitation,
Investment/benefit optimisation, Renewal planning",
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ISSN = "1028-6608",
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DOI = "doi:10.1080/10286600600789375",
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size = "16 pages",
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abstract = "The economic and social costs of pipe bursts in water
distribution networks (WDNs) are very significant.
Water managers need reliable replacement plans for
critical pipes, balancing investment with expected
benefits in a risk-based management scenario. Thus, a
robust and feasible decision support tool for water
system rehabilitation is required. This kind of tool
should incorporate (i) a model to forecast pipe
failures and (ii) a strategy to solve a multi-objective
optimisation problem trading investment vs. benefits.
The former requires the collection of company asset
data and the statistical modelling of pipe bursts. In
this article, the burst modelling is performed by the
evolutionary polynomial regression technique, providing
a symbolic model for predicting pipe bursts. The
benefits of burst reduction achieved by mains
rehabilitation are evaluated by a multi-objective
optimisation model over a short-term planning horizon
(taken to be one year in this study). The
multi-objective strategy is embedded in a genetic
algorithm search methodology. The procedure identifies
different subsets of pipes scheduled for
rehabilitation, ranging from no-replacement (i.e., no
reduction of the predicted number of bursts) to the
complete replacement scheme (i.e. maximum reduction of
the predicted number of bursts), trading cost of
rehabilitation against achieved benefits. The result of
the strategy is a Pareto (trade-off) front, which by
itself does not provide any prioritisation of pipes for
replacement. Thus, the article introduces a further
processing step by which pipes are prioritised for
rehabilitation based on the number of times each
belongs to a solution on the Pareto front. By
considering costs and such priority rating of each
main, an improved investments/benefit diagram is
constructed. The procedure is tested on a real-world UK
WDN.",
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notes = "Papers using GP related results",
- }
Genetic Programming entries for
Orazio Giustolisi
Daniele B Laucelli
Dragan Savic
Citations