Intelligent cross-entropy optimizer: A novel machine learning-based meta-heuristic for global optimization

IF 8.2 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Swarm and Evolutionary Computation Pub Date : 2024-09-25 DOI:10.1016/j.swevo.2024.101739

Salar Farahmand-Tabar, Payam Ashtari

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引用次数: 0

Abstract

Machine Learning (ML) features are extensively applied in various domains, notably in the context of Metaheuristic (MH) optimization methods. While MHs are known for their exploitation and exploration capabilities in navigating large and complex search spaces, they are not without their inherent weaknesses. These weaknesses include slow convergence rates and a struggle to strike an optimal balance between exploration and exploitation, as well as the challenge of effective knowledge extraction from complex data. To address these shortcomings, an AI-based global optimization technique is introduced, known as the Intelligent Cross-Entropy Optimizer (ICEO). This method draws inspiration from the concept of Cross Entropy (CE), a strategy that uses Kullback–Leibler or cross-entropy divergence as a measure of closeness between two sampling distributions, and it uses the potential of Machine Learning (ML) to facilitate the extraction of knowledge from the search data to learn and guide dynamically within complex search spaces. ICEO employs the Self-Organizing Map (SOM), to train and map the intricate, high-dimensional relationships within the search space onto a reduced lattice structure. This combination empowers ICEO to effectively address the weaknesses of traditional MH algorithms. To validate the effectiveness of ICEO, a rigorous evaluation involving well-established benchmark functions, including the CEC 2017 test suite, as well as real-world engineering problems have been conducted. A comprehensive statistical analysis, employing the Wilcoxon test, ranks ICEO against other prominent optimization approaches. The results demonstrate the superiority of ICEO in achieving the optimal balance between computational efficiency, precision, and reliability. In particular, it excels in enhancing convergence rates and exploration-exploitation balance.

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智能交叉熵优化器：基于机器学习的新型全局优化元启发式

机器学习（ML）功能被广泛应用于各个领域，尤其是元启发式（MH）优化方法。虽然 MH 因其在大型复杂搜索空间中的利用和探索能力而闻名，但它们并非没有固有的弱点。这些弱点包括收敛速度慢，难以在探索和利用之间取得最佳平衡，以及难以从复杂数据中有效提取知识。为了解决这些不足，我们引入了一种基于人工智能的全局优化技术，即智能交叉熵优化器（ICEO）。这种方法从交叉熵（Cross Entropy，CE）的概念中汲取灵感，CE 是一种使用库尔贝克-莱布勒（Kullback-Leibler）或交叉熵发散（cross-entropy divergence）来衡量两个采样分布之间接近程度的策略，它利用机器学习（Machine Learning，ML）的潜力来促进从搜索数据中提取知识，从而在复杂的搜索空间内进行动态学习和指导。ICEO 采用自组织图（SOM）来训练搜索空间内错综复杂的高维关系，并将其映射到缩小的网格结构上。这种组合使 ICEO 能够有效解决传统 MH 算法的弱点。为了验证 ICEO 的有效性，我们进行了一项严格的评估，其中涉及包括 CEC 2017 测试套件在内的成熟基准函数以及实际工程问题。综合统计分析采用 Wilcoxon 检验，将 ICEO 与其他著名优化方法进行了比较。结果表明，ICEO 在实现计算效率、精度和可靠性之间的最佳平衡方面更具优势。特别是，它在提高收敛速度和探索-开发平衡方面表现出色。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Swarm and Evolutionary Computation COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEC-COMPUTER SCIENCE, THEORY & METHODS

CiteScore

16.00

自引率

12.00%

发文量

169

期刊介绍： Swarm and Evolutionary Computation is a pioneering peer-reviewed journal focused on the latest research and advancements in nature-inspired intelligent computation using swarm and evolutionary algorithms. It covers theoretical, experimental, and practical aspects of these paradigms and their hybrids, promoting interdisciplinary research. The journal prioritizes the publication of high-quality, original articles that push the boundaries of evolutionary computation and swarm intelligence. Additionally, it welcomes survey papers on current topics and novel applications. Topics of interest include but are not limited to: Genetic Algorithms, and Genetic Programming, Evolution Strategies, and Evolutionary Programming, Differential Evolution, Artificial Immune Systems, Particle Swarms, Ant Colony, Bacterial Foraging, Artificial Bees, Fireflies Algorithm, Harmony Search, Artificial Life, Digital Organisms, Estimation of Distribution Algorithms, Stochastic Diffusion Search, Quantum Computing, Nano Computing, Membrane Computing, Human-centric Computing, Hybridization of Algorithms, Memetic Computing, Autonomic Computing, Self-organizing systems, Combinatorial, Discrete, Binary, Constrained, Multi-objective, Multi-modal, Dynamic, and Large-scale Optimization.