基于分解的许多目标算法性能强烈依赖于帕累托前沿形状

Performance of Decomposition-Based Many-Objective Algorithms Strongly Depends on Pareto Front Shapes

IEEE Transactions on Evolutionary Computation · 2016
被引 582 · 同刊同年前 5%
ABS 4

中文导读

本文指出基于分解的许多目标进化算法在常用测试问题上的性能提升可能导致过度专门化,并通过实验证明问题公式的微小变化会显著降低算法性能。

Abstract

Recently, a number of high performance many-objective evolutionary algorithms with systematically generated weight vectors have been proposed in the literature. Those algorithms often show surprisingly good performance on widely used DTLZ and WFG test problems. The performance of those algorithms has continued to be improved. The aim of this paper is to show our concern that such a performance improvement race may lead to the overspecialization of developed algorithms for the frequently used many-objective test problems. In this paper, we first explain the DTLZ and WFG test problems. Next, we explain many-objective evolutionary algorithms characterized by the use of systematically generated weight vectors. Then we discuss the relation between the features of the test problems and the search mechanisms of weight vector-based algorithms such as multiobjective evolutionary algorithm based on decomposition (MOEA/D), nondominated sorting genetic algorithm III (NSGA-III), MOEA/dominance and decomposition (MOEA/DD), and θ-dominance based evolutionary algorithm (θ-DEA). Through computational experiments, we demonstrate that a slight change in the problem formulations of DTLZ and WFG deteriorates the performance of those algorithms. After explaining the reason for the performance deterioration, we discuss the necessity of more general test problems and more flexible algorithms.

多目标优化进化算法测试问题算法性能