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Artificial Intelligence Review

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16.08.2022

An improved moth flame optimization algorithm based on modified dynamic opposite learning strategy

verfasst von: Saroj Kumar Sahoo, Apu Kumar Saha, Sukanta Nama, Mohammad Masdari

Erschienen in: Artificial Intelligence Review | Ausgabe 4/2023

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Abstract

Moth flame optimization (MFO) algorithm is a relatively new nature-inspired optimization algorithm based on the moth’s movement towards the moon. Premature convergence and convergence to local optima are the main demerits of the algorithm. To avoid these drawbacks, a modified dynamic opposite learning-based MFO algorithm (m-DMFO) is presented in this paper, incorporating a modified dynamic opposite learning (DOL) strategy. To validate the performance of the proposed m-DMFO algorithm, it is tested via twenty-three benchmark functions, IEEE CEC’2014 test functions and compared with a wide range of optimization algorithms. Moreover, Friedman rank test, Wilcoxon rank test, convergence analysis, and diversity measurement have been conducted to measure the robustness of the proposed m-DMFO algorithm. The numerical results show that, the proposed m-DMFO algorithm achieved superior results in more than 90% occasions. The proposed m-DMFO achieves the best rank in Friedman rank test and Wilcoxon rank test respectively. In addition, four engineering design problems have been solved by the suggested m-DMFO algorithm. According to the results, it achieves extremely impressive results, which also illustrates that the algorithm is qualified in solving real-world problems. Analyses of numerical results, diversity measure, statistical tests and convergence results ensure the enhanced performance of the proposed m-DMFO algorithm.

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Titel: An improved moth flame optimization algorithm based on modified dynamic opposite learning strategy
verfasst von: Saroj Kumar Sahoo
Apu Kumar Saha
Sukanta Nama
Mohammad Masdari
Publikationsdatum: 16.08.2022
Verlag: Springer Netherlands
Erschienen in: Artificial Intelligence Review / Ausgabe 4/2023
Print ISSN: 0269-2821
Elektronische ISSN: 1573-7462
DOI: https://doi.org/10.1007/s10462-022-10218-0

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