Regularization of an Inverse Problem for Parameter Estimation in Water Distribution Networks

Waldron, Alexander; Pecci, Filippo; Stoianov, Ivan

doi:10.1061/(asce)wr.1943-5452.0001273

Cited by 13 publications

(4 citation statements)

References 42 publications

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“…We apply the proposed optimization-based heuristic on the BWFL network shown in Figure 4. The BWFL network is an operational water distribution network within the city of Bristol (UK) and it has been used as a case study in multiple published works: [18], [3], [31], [32], [33], [34], [35]. The network is comprised of 2371 links and 2310 nodes.…”

Section: A the Bwfl Networkmentioning

confidence: 99%

Optimization-Based Selection of Hydrants and Valves Control in Water Distribution Networks for Fire Incidents Management

Nerantzis

Stoianov

2023

IEEE Systems Journal

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Section: A the Bwfl Networkmentioning

confidence: 99%

Optimization-Based Selection of Hydrants and Valves Control in Water Distribution Networks for Fire Incidents Management

Nerantzis

Stoianov

2023

IEEE Systems Journal

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“…The tank constraints (26) and the energy balance constraints (27) are the same as with NC. Variable bounds are set by constraints ( 28)- (34).…”

Section: Fire Controlmentioning

confidence: 99%

“…The BWFL network is an operational water supply network, which is part of the water distribution network of the city of Bristol in the United Kingdom, and it serves approximately 8,000 customers. It has been used as a case study in multiple published works [39,38,25,1,22,34]. The BWFL network, shown in Figure 4, is comprised of 2371 links, 2310 nodes, 2 sources of fixed head, 2 (fixed-speed) pumps, two tanks, three pressure reducing valves (PRVs) and two boundary control valves (BVs).…”

Section: The Bwfl Networkmentioning

confidence: 99%

Adaptive Model Predictive Control for Fire Incidents in Water Distribution Networks

Nerantzis

Stoianov

2022

J. Water Resour. Plann. Manage.

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Water utilities in UK aim in network pressure reduction as a means to reduce leakage, in order to meet regulatory targets and avoid financial penalties. At the same time, however, they are not legally bound to guaranty specific fire-flow rates at fire hydrants, thus posing a potential a risk to fire fighting. In the exiting literature, fire-flows in water distribution networks have been considered primarily with respect to design, vulnerability and capacity analysis, while control of pumps and valves has focused mainly on minimizing energy costs (and to a lesser extent pressure) under normal operating conditions. This study presents a (non-linear) adaptive model predictive control methodology, for water distribution networks, combining two separate modes of control: 1) Normal Control, when the network operates under normal conditions and the objective is to minimize energy costs and average zonal pressure. 2) Fire Control, when a fire incident occurs and fire-flows need to be delivered at hydrant nodes while, to the furthest possible extent, resume delivery of customer demand without over-pressuring the network. The proposed methodology is applied on an operational network from UK.

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“…It currently operates with dynamically controlled PRV and bidirectional DBV valves, which modulate flow and pressure between adjacent zones to minimize AZP. BWFLnet's current control valve configuration was applied to model existing conditions -for more details on BWFLnet see Wright et al (2014) and Waldron et al (2020). Moreover, existing kept-shut boundary valves were opened in order to test the full capabilities of the proposed solution algorithm.…”

Section: Computational Setupmentioning

confidence: 99%

Optimal design-for-control of self-cleaning water distribution networks using a convex multi-start algorithm

Jenks¹,

Pecci²,

Stoianov³

2022

Preprint

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The provision of self-cleaning velocities has been shown to reduce the risk of discolouration in water distribution networks (WDNs). Despite these findings, control implementations continue to be focused primarily on pressure and leakage management. This paper considers the control of diurnal flow velocities to maximize the self-cleaning capacity (SCC) of WDNs. We formulate a new optimal design-for-control problem where locations and operational settings of pressure control and automatic flushing valves are jointly optimized. The problem formulation includes a nonconvex objective function, nonconvex hydraulic conservation law constraints, and binary variables for modelling valve placement, resulting in a nonconvex mixed integer nonlinear programming (MINLP) optimization problem. Considering the challenges with solving nonconvex MINLP problems, we propose a heuristic algorithm which combines convex relaxations (with domain reduction), a randomization technique, and a multi-start strategy to compute feasible solutions. We evaluate the proposed algorithm on case study networks with varying size and degrees of complexity, including a large-scale operational network in the UK. The convex multi-start algorithm is shown to be a more robust solution method compared to an off-the-shelf genetic algorithm, finding good-quality feasible solutions to all design-for-control numerical experiments. Moreover, we demonstrate the implemented multi-start strategy to be a fast and scalable method for computing feasible solutions to the nonlinear SCC control problem. The proposed method extends the control capabilities and benefits of dynamically adaptive networks to improve water quality in WDNs.

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Regularization of an Inverse Problem for Parameter Estimation in Water Distribution Networks

Cited by 13 publications

References 42 publications

Optimization-Based Selection of Hydrants and Valves Control in Water Distribution Networks for Fire Incidents Management

Optimization-Based Selection of Hydrants and Valves Control in Water Distribution Networks for Fire Incidents Management

Adaptive Model Predictive Control for Fire Incidents in Water Distribution Networks

Optimal design-for-control of self-cleaning water distribution networks using a convex multi-start algorithm

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