A Knee Point-Driven Many-Objective Evolutionary Algorithm with Adaptive Switching Mechanism

Maowei He, Xu Wang, Hanning Chen, Xuguang Li
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Abstract

The Pareto dominance-based evolutionary algorithms can effectively address multiobjective optimization problems (MOPs). However, when dealing with many-objective optimization problems with more than three objectives (MaOPs), the Pareto dominance relationships cannot effectively distinguish the nondominated solutions in high-dimensional spaces. With the increase of the number of objectives, the proportion of dominance-resistant solutions (DRSs) in the population rapidly increases, which leads to insufficient selection pressure. In this paper, to address the challenges on MaOPs, a knee point-driven many-objective evolutionary algorithm with adaptive switching mechanism (KPEA) is proposed. In KPEA, the knee points determined by an adaptive strategy are introduced for not only mating selection but also environmental selection, which increases the probability of generating excellent offspring. In addition, to remove dominance-resistant solutions (DRSs) in the population, an interquartile range method is adopted, which enhances the selection pressure. Moreover, a novel adaptive switching mechanism between angle-based selection and penalty for selecting solutions is proposed, which is aimed at achieving a balance between convergence and diversity. To validate the performance of KPEA, it is compared with five state-of-the-art many-objective evolutionary algorithms. All algorithms are evaluated on 20 benchmark problems, i.e., WFG1-9, MaF1, and MaF4-13 with 3, 5, 8, and 10 objectives. The experimental results demonstrate that KPEA outperforms the compared algorithms in terms of HV and IGD in most of the test instances.
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具有自适应切换机制的膝点驱动多目标进化算法
基于帕累托优势的进化算法可以有效解决多目标优化问题(MOPs)。然而,在处理三个以上目标的多目标优化问题(MaOPs)时,帕累托优势关系无法有效区分高维空间中的非优势解。随着目标数量的增加,群体中抗支配解(DRS)的比例也会迅速增加,从而导致选择压力不足。本文提出了一种具有自适应切换机制的膝点驱动多目标进化算法(KPEA),以解决 MaOPs 面临的挑战。在 KPEA 中,由自适应策略确定的膝点不仅用于交配选择,还用于环境选择,从而提高了产生优秀后代的概率。此外,为了去除种群中的优势抗性解(DRS),还采用了四分位数区间法,从而增强了选择压力。此外,还提出了一种新的自适应切换机制,即在基于角度的选择和惩罚之间选择解决方案,旨在实现收敛性和多样性之间的平衡。为了验证 KPEA 的性能,将其与五种最先进的多目标进化算法进行了比较。所有算法都在 20 个基准问题上进行了评估,即 WFG1-9、MaF1 和 MaF4-13,目标分别为 3、5、8 和 10。实验结果表明,在大多数测试实例中,KPEA 的 HV 和 IGD 都优于其他算法。
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