Slime Mould Reproduction: A New Optimization Algorithm for Constrained Engineering Problems

Rajalakshmi Sakthivel, Kanmani Selvadurai
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Abstract

: In recent explorations of biologically inspired optimization strategies, the Slime Mould Reproduction (SMR) algorithm emerges as an innovative meta-heuristic optimization technique. This algorithm is deeply rooted in the reproductive dynamics observed in slime molds, particularly the intricate balance these organisms strike between local and global spore dispersal. By replicating this balance, the SMR algorithm deftly navigates between exploration and exploitation phases, aiming to pinpoint optimal solutions across diverse problem domains. For the purpose of evaluation, the SMR algorithm was diligently tested on three engineering problems with inherent constraints: Gear train design, three-bar truss design, and welded beam design. A comprehensive comparative study indicated that the SMR algorithm outperformed esteemed optimization techniques such as Particle Swarm Optimization (PSO), Artificial Bee Colony (ABC), Differential Evolution (DE), Grasshopper Optimization Algorithm (GOA), and Whale Optimization Algorithm (WOA) in these domains. While the exemplary performance of the SMR algorithm is worth noting, it is essential, in line with the No Free Lunch (NFL) theorem, to underscore that the performance of any optimization algorithm invariably depends on the particular problem it addresses. Nevertheless, the SMR algorithm's consistent triumph in benchmark tests underscores its potential as a formidable contender in the vast realm of optimization algorithms. The current exploration not only emphasizes the ever-expanding horizon of bio-inspired algorithms but also positions the SMR algorithm as a pivotal addition to the arsenal of optimization tools. Future implications and the potential scope of the SMR algorithm extend to various domains, from computational biology to intricate industrial designs. Envisioning its broader applicability, upcoming research avenues may delve into refining SMR's core procedures, borrowing insights from a broader range of biological behaviors for algorithmic ideation, and contemplating a binary version of the SMR algorithm, thereby amplifying its versatility in diverse optimization landscapes.
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粘液模繁殖:针对受限工程问题的新优化算法
:在最近对受生物启发的优化策略的探索中,粘菌繁殖(SMR)算法成为一种创新的元启发式优化技术。该算法深深植根于在粘菌中观察到的繁殖动态,特别是这些生物在局部和全球孢子传播之间取得的复杂平衡。通过复制这种平衡,SMR 算法能巧妙地在探索和利用阶段之间游刃有余,从而在不同的问题领域找到最佳解决方案。为了进行评估,SMR 算法在三个具有内在约束条件的工程问题上进行了认真测试:齿轮系设计、三杆桁架设计和焊接梁设计。综合比较研究表明,SMR 算法在这些领域的表现优于粒子群优化(PSO)、人工蜂群(ABC)、差分进化(DE)、蚱蜢优化算法(GOA)和鲸鱼优化算法(WOA)等著名优化技术。虽然 SMR 算法的典范性能值得注意,但根据 "天下没有免费的午餐"(NFL)定理,必须强调任何优化算法的性能始终取决于它所解决的特定问题。尽管如此,SMR 算法在基准测试中不断取得胜利,凸显了它作为广大优化算法领域的有力竞争者的潜力。目前的探索不仅强调了生物启发算法不断扩大的范围,还将 SMR 算法定位为优化工具库中的一个重要补充。SMR 算法的未来影响和潜在范围扩展到各个领域,从计算生物学到复杂的工业设计。考虑到 SMR 算法更广泛的适用性,未来的研究方向可能会深入到完善 SMR 的核心程序、从更广泛的生物行为中汲取灵感进行算法构思,以及考虑 SMR 算法的二进制版本,从而扩大其在不同优化环境中的通用性。
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
Journal of Computer Science
Journal of Computer Science Computer Science-Computer Networks and Communications
CiteScore
1.70
自引率
0.00%
发文量
92
期刊介绍: Journal of Computer Science is aimed to publish research articles on theoretical foundations of information and computation, and of practical techniques for their implementation and application in computer systems. JCS updated twelve times a year and is a peer reviewed journal covers the latest and most compelling research of the time.
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