A many-objective evolutionary algorithm under diversity-first selection based framework

Many-objective optimization problems (MaOPs) have attracted wide attention. However, most solving methods prioritize the convergence or take the convergence and diversity into account. This causes the difficulty in balancing convergence and diversity of the population still remains, especially for t...

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Bibliographic Details
Published in:Expert systems with applications 2024-09, Vol.250, p.123949, Article 123949
Main Authors: Zhang, Wei, Liu, Jianchang, Liu, Yuanchao, Liu, Junhua, Tan, Shubin
Format: Article
Language:English
Subjects:
Diversity-first selection
Evolutionary algorithm
Many-objective optimization
Objective transferring
Space projection
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Summary:Many-objective optimization problems (MaOPs) have attracted wide attention. However, most solving methods prioritize the convergence or take the convergence and diversity into account. This causes the difficulty in balancing convergence and diversity of the population still remains, especially for these problems with irregular Pareto fronts. To this end, we propose a many-objective evolutionary algorithm under diversity-first selection based framework (DSFMO), which first emphasizes the diversity and then considers the convergence. Thus, DSFMO can drive individuals to approach the Pareto front from various directions, and further achieve the balance between convergence and diversity of the population. In this framework, we first construct a candidate pool by selecting these individuals with small crowded degree (i.e., good diversity), in which the crowded degree is evaluated by the global diversity measure based on the objective transferring. Then, the individual in the constructed candidate pool that has the best convergence is selected to enter the next generation, where the convergence is evaluated by the conditional convergence measure that considers the importance of boundary individuals and evolution status. The above two steps are repeatedly executed until the next generation population is formed. In addition, a space projection assisted mating selection is developed to select high-quality parents for variation and further enhance the exploration and exploitation ability of DSFMO. Experiments on 88 test instances have shown that DSFMO can perform best on most test instances. In other words, DSFMO outperforms its seven competitors in balancing convergence and diversity of the population. •A diversity-first selection based framework is develop.•An objective transferring based global diversity measure is proposed.•A conditional convergence measure is designed.•A space projection assisted mating selection is proposed.
ISSN:0957-4174
DOI:10.1016/j.eswa.2024.123949