Enhanced EV Battery Degradation Modeling in Tropical Environments via CVAE-GRU for Sustainable Transportation

Authors

  • Hervé LOTCHOUANG FUSTE Mechatronics Laboratory Energiatronic and sustainable Mobility; Polytechnics Douala Cameroon
  • Kibong Marius Technology and Applied Sciences Laboratory, PO Box 8698 Douala, IUT Douala, Cameroon
  • Nyatte Steyve Technology and Applied Sciences Laboratory, PO Box 8698 Douala, IUT Douala, Cameroon
  • Sapnken Emmanuel Technology and Applied Sciences Laboratory, PO Box 8698 Douala, IUT Douala, Cameroon
  • Mewoli Edwige Laboratory of Engineering Civil and Mechanical, National Advanced School of Engineering, University of Yaoundé, P.O Box 8390, Yaoundé, Cameroon
  • Tamba Gaston Technology and Applied Sciences Laboratory, PO Box 8698 Douala, IUT Douala, Cameroon

DOI:

https://doi.org/10.34123/icdsos.v2025i1.610

Keywords:

Battery Degradation, CVAE-GRU, Electric Vehicles, Multicollinearity, Tropical Climate

Abstract

Electric Vehicle (EV) battery degradation in tropical environments remains poorly understood, with traditional linear models like OLS facing significant challenges such as multicollinearity, leading to unreliable insights into influential factors. This study aims to experimentally characterize lithium-ion battery degradation and comprehensively evaluate the influence of local climatic (temperature, humidity, dust) and driving conditions (road quality, mileage) in a Cameroonian tropical context, addressing the limitations of conventional statistical approaches. Our unique contribution involves providing empirical real-world data from a subSaharan environment and applying a novel hybrid CVAE-GRU methodology to capture complex non-linear and temporal dependencies. An embedded system continuously collected battery parameters (SoH, internal resistance) alongside environmental and driving data. The CVAE learns robust latent representations from these correlated inputs, while the GRU models their temporal dynamics for degradation prediction. Results confirm progressive SoH degradation, significantly accelerated by high temperatures, humidity, dust, and poor road quality. The CVAE-GRU approach effectively mitigates multicollinearity, offering superior accuracy and deeper insights into these influences. This work highlights the critical impact of tropical conditions on EV battery aging, providing crucial findings for developing adapted Battery Management Systems and fostering sustainable mobility in similar regions.

Downloads

Published

2025-12-22

How to Cite

LOTCHOUANG FUSTE, H., Marius, K., Steyve, N., Emmanuel, S., Edwige, M., & Gaston, T. (2025). Enhanced EV Battery Degradation Modeling in Tropical Environments via CVAE-GRU for Sustainable Transportation. Proceedings of The International Conference on Data Science and Official Statistics, 2025(1), 331–351. https://doi.org/10.34123/icdsos.v2025i1.610

Issue

Vol. 2025 No. 1 (2025): Proceedings of 2025 International Conference on Data Science and Official Statistics (ICDSOS)

Section

Data Science