Robust optimization for water distribution systems least cost design

Perelman, Lina; Housh, Mashor; Ostfeld, Avi

doi:10.1002/wrcr.20539

Cited by 50 publications

(36 citation statements)

References 30 publications

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“…Several applications have shown that taking parameter uncertainties into account may have significant influence on the results. For example Pasha and Lansey (2010) investigate the e ect of parameter uncertainties on water quality using the Monte Carlo method and Perelman et al (2013) investigate the influence of uncertainties in the context of least-cost design for water distribution networks.…”

Section: Introductionmentioning

confidence: 99%

A Spectral Approach to Uncertainty Quantification in Water Distribution Networks

Braun

Piller

Iollo

et al. 2020

J. Water Resour. Plann. Manage.

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To date, the hydraulics of water distribution networks are calculated using deterministic models.Regarding the fact that many of the parameters in these models are not known exactly, it is important to evaluate the e ects of their uncertainties on the results through Uncertainty Analysis. For the propagation of uncertain parameters, this article for the first time applies the Polynomial Chaos expansion to a hydraulic model and compares the results to classical approaches like the First Order Second Moment method and Monte Carlo simulations. Results presented in this article show that the accuracy of the Polynomial Chaos expansion is on the same level as the Monte Carlo simulation.Further, it is concluded that due to its computational e ciency the Polynomial Chaos Expansion is superior to the Monte Carlo simulation.

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Section: Introductionmentioning

confidence: 99%

A Spectral Approach to Uncertainty Quantification in Water Distribution Networks

Braun

Piller

Iollo

et al. 2020

J. Water Resour. Plann. Manage.

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“…An approach to dealing with the uncertainty of demand consists in explicitly considering different possible realizations of its value at the nodes of a WDN, i.e., different loading scenarios and associating to each of them a measure of their probability. So, it is possible to find a feasible solution which is also as close as possible to the optimum for all the scenarios: this scenario-based approach is known as robust optimization [3]. In the same way it is possible also to derive WDN reliability [4] or to localize leakages [5] or to map pressure-heads for a real-time control [6], all under uncertain demand conditions.…”

Section: Introductionmentioning

confidence: 99%

Generating Scenarios of Cross-Correlated Demands for Modelling Water Distribution Networks

Magini

Boniforti

Guercio

2019

Water

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A numerical approach for generating a limited number of water demand scenarios and estimating their occurrence probabilities in a water distribution network (WDN) is proposed. This approach makes use of the demand scaling laws in order to consider the natural variability and spatial correlation of nodal consumption. The scaling laws are employed to determine the statistics of nodal consumption as a function of the number of users and the main statistical features of the unitary user’s demand. Besides, consumption at each node is considered to follow a Gamma probability distribution. A high number of groups of cross-correlated demands, i.e., scenarios, for the entire network were generated using Latin hypercube sampling (LHS) and the numerical procedure proposed by Iman and Conover. The Kantorovich distance is used to reduce the number of scenarios and estimate their corresponding probabilities, while keeping the statistical information on nodal consumptions. By hydraulic simulation, the whole number of generated demand scenarios was used to obtain a corresponding number of pressure scenarios on which the same reduction procedure was applied. The probabilities of the reduced scenarios of pressure were compared with the corresponding probabilities of demand.

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“…At regional scale, these include design and operation of water systems under future demand and water availability uncertainty (Chung et al, 2009;Housh et al, 2013), creation of new water resources by producing high quality water from saline or brackish water (Avni et al, 2013) and waste water reclamation (Zhang et al, 2013). At local scale, previous works focus on water distribution system design under demand (Babayan et al, 2005;Perelman et al, 2013) and hydraulic model uncertainty (Fu and Kapelan, 2011;Laucelli et al, 2012), operation for leakage control (Giustolisi et al, 2008;Ulanicki et al, 2008;Price and Ostfeld, 2014), and reduction of potable water demand by on-site graywater reuse (Penn et al, 2013).…”

Section: Graphical Abstract 1 Introductionmentioning

confidence: 99%

Automated sub-zoning of water distribution systems

Perelman

Allen

Preis

et al. 2015

Environmental Modelling & Software

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Water distribution systems (WDS) are complex pipe networks with looped and branching topologies that often comprise of thousands to tens of thousands of links and nodes. This work presents a generic framework for improved analysis and management of WDS by partitioning the system into smaller (almost) independent sub-systems with balanced loads and minimal number of interconnection. This paper compares the performance of three classes of unsupervised learning algorithms from graph theory for practical sub-zoning of WDS: (1) Global clustering -a bottom-up algorithm for clustering n objects with respect to a similarity function, (2) Community structure -a bottom-up algorithm based on network modularity property, which is a measure of the quality of network partition to clusters versus randomly generated graph with respect to the same nodal degree, and (3) Graph partitioning -a flat partitioning algorithm for dividing a network with n nodes into k clusters, such that the total weight of edges crossing between clusters is minimized and the loads of all the clusters are balanced. The algorithms are adapted to WDS to provide a practical decision support tool for water utilities. Visual qualitative and quantitative measures are proposed to evaluate models' performance. The proposed methods are applied and results are evaluated and compared for two large-scale water distribution systems serving heavily populated areas in Singapore.

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Robust optimization for water distribution systems least cost design

Cited by 50 publications

References 30 publications

A Spectral Approach to Uncertainty Quantification in Water Distribution Networks

A Spectral Approach to Uncertainty Quantification in Water Distribution Networks

Generating Scenarios of Cross-Correlated Demands for Modelling Water Distribution Networks

Automated sub-zoning of water distribution systems

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