A modified multi-objective grey wolf optimizer for multi-objective flood control operation of cascade reservoirs

[Display omitted] •MMOGWO integrates spiral hunting and sudden leap strategies to avoid local optima.•MMOGWO demonstrates significant advantages on most of benchmark functions.•HV value of MMOGWO is 10 % higher than that of NSGA-III and MOEA/D for floods.•MMOGWO reduces flood peaks by 50 % and impro...

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Vydané v:Journal of hydrology (Amsterdam) Ročník 658; s. 133162
Hlavní autori: Liu, Chenye, Xie, Yangyang, Liu, Saiyan, Mirjalili, Seyedali, Qin, Jiyao, Wei, Jianfeng, Fang, Hongyuan, Du, Huihua
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier B.V 01.09.2025
Predmet:
algorithms
Aquila chrysaetos
Cascade reservoirs
decision making
domain
dung beetles
flood control
Flood control operation
Grey wolf optimizer
hydrology
Manta
Multi-objective optimization
Pareto front
Pareto front
Multi-objective optimization
Flood control operation
Grey wolf optimizer
Cascade reservoirs
ISSN:0022-1694
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Shrnutí:[Display omitted] •MMOGWO integrates spiral hunting and sudden leap strategies to avoid local optima.•MMOGWO demonstrates significant advantages on most of benchmark functions.•HV value of MMOGWO is 10 % higher than that of NSGA-III and MOEA/D for floods.•MMOGWO reduces flood peaks by 50 % and improves resilience to consecutive floods. The issue of reservoir flood control optimization (RFCO) is inherently intricate as it involves a large number of variables and multiple objectives. In the realm of RFCO, numerous multi-objective algorithms are prone to the dimensional disaster, often becoming ensnared in local optima and failing to provide decision-makers with diverse solutions. This paper introduces a modified multi-objective grey wolf optimizer (MMOGWO) that integrates multiple search strategy, enhancing the autonomous exploration capabilities of individual grey wolves. It addresses the weaknesses of original multi-objective grey wolf optimizer (MOGWO) in exploration and its propensity to converge to local optima. MMOGWO was evaluated on well-known multi-objective optimization benchmark functions UF8-UF10, DTLZ2 and DTLZ7. Experimental results from Wilcoxon signed-rank tests and Friedman tests demonstrate the algorithm’s strong competitiveness, as it holds an advantage in comparisons with MOGWO, non-dominated Sorting Dung Beetle Optimizer (NSDBO), multi-objective golden eagle optimizer (MOGEO), and multi-objective Manta ray foraging optimizer (MOMRFO). Subsequently, MMOGWO was applied to a flood control operation model that considers the safety of cascade reservoirs, the safety of downstream protected objects, and the ability of cascade reservoirs to manage consecutive floods. The results show that MMOGWO significantly outperforms widely-used algorithms such as NSGA-III and MOEA/D in high-dimensional RFCO problems. This can be attributed to MMOGWO’s broader solution coverage, whereas the solutions of NSGA-III and MOEA/D are mostly concentrated in a narrow range, indicating their entrapment in local optima while MMOGWO achieves global optimization and provides a more diverse set of feasible solutions. The MMOGWO algorithm presented in this paper emerges as a reliable optimizer for flood control operation of cascade reservoirs and can be regarded as a competitive multi-objective optimization algorithm.
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ISSN:0022-1694
DOI:10.1016/j.jhydrol.2025.133162