Abstract
In recent years, a number of recombination operators have been proposed for multiobjective evolutionary algorithms (MOEAs). One kind of recombination operators is designed based on the Gaussian process model. However, this approach only uses one standard Gaussian process model with fixed variance, which may not work well for solving various multiobjective optimization problems (MOPs). To alleviate this problem, this paper introduces a decomposition-based multiobjective evolutionary optimization with adaptive multiple Gaussian process models, aiming to provide a more effective heuristic search for various MOPs. For selecting a more suitable Gaussian process model, an adaptive selection strategy is designed by using the performance enhancements on a number of decomposed subproblems. In this way, our proposed algorithm owns more search patterns and is able to produce more diversified solutions. The performance of our algorithm is validated when solving some well-known F, UF, and WFG test instances, and the experiments confirm that our algorithm shows some superiorities over six competitive MOEAs.
Highlights
Multiobjective optimization problems (MOPs) widely exist in the fields of scientific research and engineering applications
The proposed multiobjective evolutionary algorithms (MOEAs)/D-AMG is compared with six competitive MOEAs, including MOEA/D-SBX, MOEA/D-differential evolution (DE), MOEA/ D-GM, RM-MEDA, IM-MOEA, and AMEDA. e results obtained by these algorithms on the 28 test problems are given in Tables 1 and 2, regarding the Inverted Generational Distance (IGD) and HV metrics, respectively
Multiple Gaussian process models are used in MOEA/D-AMG, which can help to solve various kinds of MOPs
Summary
Multiobjective optimization problems (MOPs) widely exist in the fields of scientific research and engineering applications. For the inverse model methods for variation, it is very changeling for mapping from the objective space into the decision space when tackling some complicated MOPs. EDAs usually adopt one standard Gaussian process model with fixed variance, which may not work well for various kinds of MOPs. To enhance the search capability of EDAs, this paper introduces a decomposition-based MOEA with adaptive multiple Gaussian process models, called MOEA/ D-AMG, which is effective in generating more superior offspring. Based on the performance enhancements on a number of decomposed subproblems, one suitable Gaussian process model will be selected In this way, our method is more intelligent and can provide more search patterns to produce the diversified solutions.
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