Enhancing Multi-Objective Optimization: A Decomposition-Based Approach Using the Whale Optimization Algorithm

Optimization techniques aim to identify optimal solutions for a given problem. In single-objective optimization, the best solution corresponds to the one that maximizes or minimizes the objective function. However, when dealing with multi-objective optimization, particularly when the objectives are...

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Vydané v:Mathematics (Basel) Ročník 13; číslo 5; s. 767
Hlavní autori: Ramos-Frutos, Jorge, Casas-Ordaz, Angel, Zapotecas-Martínez, Saúl, Oliva, Diego, Valdivia-González, Arturo, García-Nájera, Abel, Pérez-Cisneros, Marco
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Basel MDPI AG 01.03.2025
Predmet:
Algorithms
Analysis
Approximation
Archives & records
Business metrics
Cetacea
Decomposition
decomposition-based optimization
Genetic algorithms
Heuristic methods
Mathematical optimization
Methods
multi-objective evolutionary optimization
Multiple objective analysis
Objectives
Optimization
Optimization algorithms
Pareto optimum
whale optimization algorithm
Whales & whaling
United States
Germany
ISSN:2227-7390, 2227-7390
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Shrnutí:Optimization techniques aim to identify optimal solutions for a given problem. In single-objective optimization, the best solution corresponds to the one that maximizes or minimizes the objective function. However, when dealing with multi-objective optimization, particularly when the objectives are conflicting, identifying the best solution becomes significantly more complex. In such cases, exact or analytical methods are often impractical, leading to the widespread use of heuristic and metaheuristic approaches to identify optimal or near-optimal solutions. Recent advancements have led to the development of various nature-inspired metaheuristics designed to address these challenges. Among these, the Whale Optimization Algorithm (WOA) has garnered significant attention. An adapted version of the WOA has been proposed to handle multi-objective optimization problems. This work extends the WOA to tackle multi-objective optimization by incorporating a decomposition-based approach with a cooperative mechanism to approximate Pareto-optimal solutions. The multi-objective problem is decomposed into a series of scalarized subproblems, each with a well-defined neighborhood relationship. Comparative experiments with seven state-of-the-art bio-inspired optimization methods demonstrate that the proposed decomposition-based multi-objective WOA consistently outperforms its counterparts in both real-world applications and widely used benchmark test problems.
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ISSN:2227-7390
2227-7390
DOI:10.3390/math13050767