AI-Driven Smart Factories: From Predictive Maintenance to Autonomous Production Systems

Authors

  • Wasiu Oyediran Adedeji Department of Mechatronics Engineering, Osun State University.
  • Oriyomi Olasunkanmi Adetayo Department of Mechatronics Engineering, Osun State University.
  • Josiah Pelemo Department of Weldering and Fabrication Engineering, Yaba College of Technology, Yaba.
  • Babajide Joshua Oderinde Department of Mechatronics Engineering, Osun State University.
  • Iliyasu Kayode Okediran Department of Mechanical Engineering, Osun State University.
  • Micheal Ifeanyi Molokwu Department of Weldering and Fabrication Engineering, Nigerian Naval Institute of Technology, Sapele.
  • Mercy Opeyemi Owoyomi Department of Mechatronics Engineering, Osun State University.
  • Jesuye Adufe Department of Mechatronics Engineering, Osun State University.

DOI:

https://doi.org/10.63561/jca.v2i4.1078

Keywords:

Industry 4.0, Smart Factories, Predictive Maintenance, Autonomous Production Systems, Artificial Intelligence

Abstract

The fourth industrial revolution (Industry 4.0) has reformed manufacturing through the integration of artificial intelligence (AI), Internet of Things (IoT), big data analytics, cloud computing and advanced robotics, 5G connectivity, and emerging technologies like quantum computing and augmented reality (AR). Smart factories, characterized by interconnected, data-driven ecosystems, optimize operational efficiency, reduce downtime, enhance sustainability, and enable autonomous production systems. This paper provides an expansive, multidimensional analysis of AI-driven smart factories, focusing on the evolution from predictive maintenance (PdM) to fully autonomous production systems. By synthesizing advancements in machine learning (ML), IoT, digital twins, generative AI, edge computing, 5G, and emerging technologies, the study evaluates their impact on efficiency, cost reduction, sustainability, workforce dynamics, ethical considerations, and regulatory compliance. Key challenges, including data quality, AI explain ability, system integration, cybersecurity, workforce reskilling, and regulatory frameworks, are thoroughly examined, alongside opportunities for innovation. Findings demonstrate that PdM achieves up to 97.3% accuracy in failure prediction, reducing downtime by 50% and costs by 10–40%, while autonomous systems, exemplified by Tesla’s Gigafactory, boost throughput by 30%. Future directions, including explainable AI (XAI), federated learning, self-aware assets, human-AI collaboration, and quantum computing, are proposed to foster resilient, sustainable, and inclusive manufacturing ecosystems.

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Published

2025-12-30

How to Cite

Adedeji, W. O., Adetayo, O. O., Pelemo, J., Oderinde, B. J., Okediran, I. K., Molokwu, M. I., … Adufe, J. (2025). AI-Driven Smart Factories: From Predictive Maintenance to Autonomous Production Systems. Faculty of Natural and Applied Sciences Journal of Computing and Applications, 2(4), 87–94. https://doi.org/10.63561/jca.v2i4.1078

Issue

Vol. 2 No. 4 (2025): 2025-FNAS-JCA-2-4

Section

Articles

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