Water reservoirs quality management using meta-heuristic Algorithms: Analysis and optimization of water quality considering uncertainties

Managing reservoir water quality under uncertainty remains a critical challenge in contemporary water resource management. This study introduces a robust simulation–optimization meta-model framework to enhance reservoir outflow quality, focusing on minimizing Total Dissolved Solids (TDS) concentrati...

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Vydáno v:Physics and chemistry of the earth. Parts A/B/C Ročník 140; s. 103987
Hlavní autoři: Hassani, Seyedeh Zahra, Ashofteh, Parisa-Sadat, Hoseini Vaez, Seyed Rohollah
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Ltd 01.10.2025
Témata:
CE-QUAL-W2 model
EVPS algorithm
Particle swarm optimization
Uncertainty
Water reservoir quality management
Uncertainty
Water reservoir quality management
Particle swarm optimization
CE-QUAL-W2 model
EVPS algorithm
ISSN:1474-7065
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Shrnutí:Managing reservoir water quality under uncertainty remains a critical challenge in contemporary water resource management. This study introduces a robust simulation–optimization meta-model framework to enhance reservoir outflow quality, focusing on minimizing Total Dissolved Solids (TDS) concentrations. To circumvent the computational limitations of high-fidelity simulators, a Supervised Learning (SL) surrogate model was developed as a substitute for the CE-QUAL-W2 simulator. Achieving a prediction accuracy of 85 %, the SL model effectively captures complex, nonlinear interactions within water quality dynamics. Two hybrid metaheuristic frameworks—Particle Swarm Optimization integrated with SL (PSO-SL) and Enhanced Vibrating Particle System integrated with SL (EVPS-SL)—were implemented to optimize reservoir outflows under uncertainty. Both approaches successfully balanced the competing objectives of meeting downstream water demand and minimizing TDS concentrations, while significantly reducing computational costs and improving convergence behavior. The rigorously calibrated CE-QUAL-W2 model demonstrated high validation scores (NSE = 0.99 for storage volume and 1.00 for water level; PBIAS = −0.05 % and −0.0004 %, respectively), confirming its reliability for surrogate training. Additionally, the study examined uncertainty propagation using two widely adopted sampling techniques: Monte Carlo Simulation and Latin Hypercube Sampling (LHS). Optimization outcomes were assessed using performance metrics—reliability, vulnerability, and resilience. The PSO-SL model, coupled with Monte Carlo sampling, exhibited the most balanced performance, achieving 41 % reliability and 26 % vulnerability. In contrast, EVPS-SL with LHS demonstrated faster convergence (30 % reduction in computational time) but yielded lower reliability (16 %) and higher vulnerability (87 %). This research not only advances reservoir water quality management under uncertainty but also contributes methodologically to the integration of data-driven surrogates and optimization within environmental systems modeling. •A data-driven surrogate model based on SL was developed to emulate the CE-QUAL-W2.•A novel integration of the EVPS algorithm with the SL was introduced to optimize TDS concentrations.•Application of SL-based surrogates with both EVPS and PSO under inflow scenarios was used.•Monte Carlo and LHS techniques were employed to assess sampling strategies in uncertainty.
ISSN:1474-7065
DOI:10.1016/j.pce.2025.103987