A Scalable Fog Computing Solution for Industrial Predictive Maintenance and Customization

This study presents a predictive maintenance system designed for industrial IoT environ- 1 ments, focusing on resource efficiency and adaptability. The system utilizes Nicla Sense ME sensors, 2 a Raspberry Pi-based concentrator for real-time monitoring, and an LSTM machine-learning model 3 for predictive analysis. Notably, the LSTM algorithm is an example of how the system’s sandbox 4 environment can be used, allowing external users to easily integrate custom models without altering 5 the core platform. In the laboratory, the system achieved a Root Mean Squared Error (RMSE) of 6 0.0156, with high accuracy across all sensors, detecting intentional anomalies with a 99.81% accuracy 7 rate. In the real-world phase, the system maintained robust performance, with sensors recording 8maximum Mean Absolute Errors (MAE) of 0.1821, an R-squared value of 0.8898, and a Mean Absolute 9 Percentage Error (MAPE) of 0.72%, demonstrating precision even in the presence of environmental 10 interferences. Additionally, the architecture supports scalability, accommodating up to 64 sensor 11 nodes without compromising performance. The sandbox environment enhances the platform’s 12 versatility, enabling customization for diverse industrial applications. The results highlight the 13 significant benefits of predictive maintenance in industrial contexts, including reduced downtime, 14 optimized resource use, and improved operational efficiency. These findings underscore the potential 15 of integrating AI-driven predictive maintenance into constrained environments, offering a reliable 16 solution for dynamic, real-time industrial operations.