Water distribution system model calibration under uncertainty environments

Takahashi, S.; Saldarriaga, Juan; Vega, Magdalena Correa; Hernández, F.

doi:10.2166/ws.2010.906

Cited by 11 publications

(6 citation statements)

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“…Another inherent drawback is the dependence on well calibrated (accurate) hydraulic models for large networks. Beyond the implicit non-linearity, the number of parameters involved in the hydraulic equations and their large number of possible combinations introduce high complexity to the WDN calibration problem (an NP-Hard problem, which cannot be solved in polynomial time Takahashi et al (2010).) For large WDNs, these have an expensive computational cost since, even for moderate size networks, the number of possible failure scenarios grows exponentially and are approached using either some linearising assumptions or the use of heuristics for failure simulations (Berardi et al 2014).…”

Section: Introductionmentioning

confidence: 99%

A Graph-Theoretic Framework for Assessing the Resilience of Sectorised Water Distribution Networks

Herrera

Abraham

Stoianov

2016

Water Resour Manage

138

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Water utilities face a challenge in maintaining a good quality of service under a wide range of operational management and failure conditions. Tools for assessing the resilience of water distribution networks are therefore essential for both operational and maintenance optimization. In this paper, a novel graph-theoretic approach for the assessment of resilience for large scale water distribution networks is presented. This is of great importance for the management of large scale water distribution systems, most models containing up to hundreds of thousands of pipes and nodes. The proposed framework is mainly based on quantifying the redundancy and capacity of all possible routes from demand nodes to their supply sources. This approach works well with large network sizes since it does not rely on precise hydraulic simulations, which require complex calibration processes and computation, while remaining meaningful from a physical and a topological point of view. The proposal is also tailored for the analysis of sectorised networks through a novel multiscale method for analysing connectivity, which is successfully tested in operational utility network models made of more than 100,000 nodes and 110,000 pipes.

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Section: Introductionmentioning

confidence: 99%

A Graph-Theoretic Framework for Assessing the Resilience of Sectorised Water Distribution Networks

Herrera

Abraham

Stoianov

2016

Water Resour Manage

138

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“…Barco et al, 2008;Merz et al, 2010b;Takahashi et al, 2010). When a model proves capable of reproducing the response of a drainage system to a specific storm event (or several storm events), then modellers are in a good position to characterise the effects of proposed changes to infrastructure such as new sewer lines, detention basins and pump stations.…”

Section: Introductionmentioning

confidence: 99%

Calibration of stormwater management model using flood extent data

Kim

Sanders

Han

et al. 2014

Proceedings of the Institution of Civil Engineers - Water Manag

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The Seogu (western) portion of Daegu, Korea experiences chronic urban flooding and there is a need to increase flood detention and storage to reduce flood impacts. Since the site is densely developed, use of an underground car park as a cistern has been proposed. The stormwater management model (SWMM) is applied to study alternative hydraulic designs and overall performance, and it is shown that by linking SWMM to a two-dimensional flood inundation model, SWMM parameters can be calibrated from observations of flood extent. Calibration would otherwise not be possible because storm sewer flows are not internally monitored. This study reveals a significant sensitivity in SWMM relative to surcharge prediction, demonstrates a creative repurposing of urban infrastructure to manage extreme flood events and shows the importance of flood documentation relative to drainage infrastructure analysis and design.

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“…In evaluating the performance of a calibrated water distribution network model, most researchers commonly used mean absolute error or relative error (e.g., refs. [16,17]) and correlation coefficient (e.g., ref. [18]) to compare the simulated results and observed data.…”

Section: Introductionmentioning

confidence: 99%

Model Performance Indicator of Aging Pipes in a Domestic Water Supply Distribution Network

Rahman

Muhammad

Abdullah

et al. 2019

Water

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Aging pipes in the domestic water distribution network have the potential to decrease the quality and quantity of the treated water supplied to the consumers. Therefore, a calibrated water distribution model is helpful to monitor and understand the behaviour of a real water distribution network. However, a comprehensive performance indicator and an integrated method to assess the efficiency of model performance have not been well established in the literature. This study developed a methodology for a model calibration exercise, with consideration of two uncertainty parameters, i.e., Hazen–Williams roughness coefficient of the pipes and Non-Revenue Water (NRW) in each nodal demand. Following this, a statistical color-coded performance indicator was established, based on the Nash–Sutcliffe Efficiency Coefficient (NSEC), the coefficient of determination (R2), the correlation coefficient (r), and the Mean Absolute Error (MAE). The accuracy of the calibrated model was measured by Discrepancy Ratio (DR) analysis. This study concluded that the model performed well when NRW was added to the nodal demand in zone(s) with suspected water loss activities. The suggested Hazen–Williams roughness coefficient for PVC pipes was between 130 and 140 for pipes aged more than 20 years. The threshold error value to determine the accuracy of the simulated model was proposed to be between –0.05 and 0.05.

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Water distribution system model calibration under uncertainty environments

Cited by 11 publications

References 0 publications

A Graph-Theoretic Framework for Assessing the Resilience of Sectorised Water Distribution Networks

A Graph-Theoretic Framework for Assessing the Resilience of Sectorised Water Distribution Networks

Calibration of stormwater management model using flood extent data

Model Performance Indicator of Aging Pipes in a Domestic Water Supply Distribution Network

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