Introduction: Data-driven modelling in the fields of science, engineering, and health has been revolutionized by the rapid development of machine learning (ML). However, the majority of current machine learning frameworks rely on traditional integer-order calculus, which frequently falls short of capturing memory effects, long-term relationships, and inherited characteristics present in many real-world systems.

Method: The goal of this study is to develop and analyze fractional-order machine learning architectures, including fractional dynamic systems for time-series prediction, fractional neural networks, and fractional gradient-based optimization methods. Applications in biomedical signal processing, epidemiological modelling, and socio-behavioral systems, where memory effects and delayed reactions are critical, will receive special attention. The project aims to improve model accuracy, stability, and interpretability in complicated situations by integrating Caputo and Riemann–Liouville fractional derivatives into learning dynamics.

Results: Despite its potential, several obstacles hinder the application of fractional calculus in machine learning, including the lack of standardized training frameworks, increased computational costs, numerical instability, and parameter identifiability issues. In order to facilitate practical implementation, this study will methodically investigate these difficulties and suggest effective numerical methods, regularization techniques, and scalable algorithms. A unified theoretical framework for fractional-order learning systems, validated application case studies, and open-source computational tools to facilitate additional study in this developing subject are among the anticipated results.

Conclusion: This project intends to contribute to the next generation of intelligent systems that can more accurately model memory-dependent phenomena by bridging cutting-edge mathematical theory with contemporary artificial intelligence techniques. This will advance machine learning theory and practice in complex, real-world settings.