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Main Authors: Esfahani, Faramarz Safi, Beydoun, Ghassan, Saberi, Morteza, McCusker, Brad, Pradhan, Biswajeet
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.13808
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author Esfahani, Faramarz Safi
Beydoun, Ghassan
Saberi, Morteza
McCusker, Brad
Pradhan, Biswajeet
author_facet Esfahani, Faramarz Safi
Beydoun, Ghassan
Saberi, Morteza
McCusker, Brad
Pradhan, Biswajeet
contents Metaheuristic algorithms are widely used for solving complex optimization problems, yet their effectiveness is often constrained by fixed structures and the need for extensive tuning. The Polymorphic Metaheuristic Framework (PMF) addresses this limitation by introducing a self-adaptive metaheuristic switching mechanism driven by real-time performance feedback and dynamic algorithmic selection. PMF leverages the Polymorphic Metaheuristic Agent (PMA) and the Polymorphic Metaheuristic Selection Agent (PMSA) to dynamically select and transition between metaheuristic algorithms based on key performance indicators, ensuring continuous adaptation. This approach enhances convergence speed, adaptability, and solution quality, outperforming traditional metaheuristics in high-dimensional, dynamic, and multimodal environments. Experimental results on benchmark functions demonstrate that PMF significantly improves optimization efficiency by mitigating stagnation and balancing exploration-exploitation strategies across various problem landscapes. By integrating AI-driven decision-making and self-correcting mechanisms, PMF paves the way for scalable, intelligent, and autonomous optimization frameworks, with promising applications in engineering, logistics, and complex decision-making systems.
format Preprint
id arxiv_https___arxiv_org_abs_2505_13808
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle RAG/LLM Augmented Switching Driven Polymorphic Metaheuristic Framework
Esfahani, Faramarz Safi
Beydoun, Ghassan
Saberi, Morteza
McCusker, Brad
Pradhan, Biswajeet
Neural and Evolutionary Computing
Artificial Intelligence
Metaheuristic algorithms are widely used for solving complex optimization problems, yet their effectiveness is often constrained by fixed structures and the need for extensive tuning. The Polymorphic Metaheuristic Framework (PMF) addresses this limitation by introducing a self-adaptive metaheuristic switching mechanism driven by real-time performance feedback and dynamic algorithmic selection. PMF leverages the Polymorphic Metaheuristic Agent (PMA) and the Polymorphic Metaheuristic Selection Agent (PMSA) to dynamically select and transition between metaheuristic algorithms based on key performance indicators, ensuring continuous adaptation. This approach enhances convergence speed, adaptability, and solution quality, outperforming traditional metaheuristics in high-dimensional, dynamic, and multimodal environments. Experimental results on benchmark functions demonstrate that PMF significantly improves optimization efficiency by mitigating stagnation and balancing exploration-exploitation strategies across various problem landscapes. By integrating AI-driven decision-making and self-correcting mechanisms, PMF paves the way for scalable, intelligent, and autonomous optimization frameworks, with promising applications in engineering, logistics, and complex decision-making systems.
title RAG/LLM Augmented Switching Driven Polymorphic Metaheuristic Framework
topic Neural and Evolutionary Computing
Artificial Intelligence
url https://arxiv.org/abs/2505.13808