A Novel Approach for Enhancing Battery Reliability in Market Using Machine Learning-Based RUL Prediction

Babu, Ch. Rajendra; Swapna, Thalla; Lakshmi, Ramisetty Siva Naga; Sankar, Avanigadda Durga; Reddy, Bezawada Naga Venkata

A Novel Approach for Enhancing Battery Reliability in Market Using Machine Learning-Based RUL Prediction

Ch. Rajendra Babu (), Thalla Swapna, Ramisetty Siva Naga Lakshmi, Avanigadda Durga Sankar and Bezawada Naga Venkata Reddy
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Ch. Rajendra Babu: Lakireddy Balireddy College of Engineering (Autonomous) Permanently Affiliated to JNTUK
Thalla Swapna: Lakireddy Bali Reddy College of Engineering
Ramisetty Siva Naga Lakshmi: Lakireddy Bali Reddy College of Engineering
Avanigadda Durga Sankar: Lakireddy Bali Reddy College of Engineering
Bezawada Naga Venkata Reddy: Lakireddy Bali Reddy College of Engineering

Chapter 12 in Leveraging Emerging Technologies and Analytics for Empowering Humanity, Vol. 1, 2025, pp 229-244 from Springer

Abstract: Abstract Batteries are fundamental to modern life because they run critical systems and gadgets in various industries, such as emergency response, logistics, and healthcare. Rechargeable battery packs are in greater demand, especially for energy storage and electric cars, emphasizing their significance in the worldwide energy transition. Dong (Wang et al., Microelectronics Reliability, ScienceDirect 78:212–219, 2017) Predicting the battery’s Remaining Useful Life (RUL) is the essential for the maintenance planning and resource management optimization. This work uses cutting-edge Machine Learning (ML) techniques to create a predictive model to calculate RUL based on past battery data. The techniques used included linear regression, complicated algorithms like XGBoost and AdaBoost, and ensemble approaches like Random Forest and Gradient Boosting. With an astounding 99.98% accuracy rate, the XGBoost model proved useful for predicting battery RUL. Important parameters were found to include voltage and discharge. Important criteria that greatly impact battery longevity include discharge and voltage. By reliably predicting the RUL of batteries for fresh, unknown data, the final trained model promotes sustainable battery usage across various applications, improves operational efficiency, and allows for well-informed decision-making.

Keywords: Remaining Usage Life (RUL); Ensemble Approaches; Mean Absolute Error (MAE); XGBoost Algorithm; Predictive Modelling; Machine Learning (ML) Algorithms; Root Mean Squared Error (RMSE) (search for similar items in EconPapers)
Date: 2025
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DOI: 10.1007/978-981-96-2548-2_12

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