Towards a Probabilistic Fusion Approach for Robust Battery Prognostics

  1. Alcibar, Jokin 1
  2. Aizpurua, Jose I. 12
  3. Zugasti, Ekhi 1
  1. 1 Electronics & Computer Science Department, Mondragon University, Spain
  2. 2 Ikerbasque, Basque Foundation for Science, Bilbao, Spain
Proceedings:
PHM Society European Conference

ISSN: 2325-016X

ISBN: 978-1-936263-40-0

Year of publication: 2024

Volume: 8

Issue: 1

Pages: 13

Type: Conference paper

DOI: 10.36001/PHME.2024.V8I1.3981 GOOGLE SCHOLAR lock_openOpen access editor

Abstract

Batteries are a key enabling technology for the decarbonization of transport and energy sectors. The safe and reliable operation of batteries is crucial for battery-powered systems. In this direction, the development of accurate and robust battery state-of-health prognostics models can unlock the potential of autonomous systems for complex, remote and reliable operations. The combination of Neural Networks, Bayesian modelling concepts and ensemble learning strategies, form a valuable prognostics framework to combine uncertainty in a robust and accurate manner. Accordingly, this paper introduces a Bayesian ensemble learning approach to predict the capacity depletion of lithium-ion batteries. The approach accurately predicts the capacity fade and quantifies the uncertainty associated with battery design and degradation processes. The proposed Bayesian ensemble methodology employs a stacking technique, integrating multiple Bayesian neural networks (BNNs) as base learners, which have been trained on data diversity. The proposed method has been validated using a battery aging dataset collected by the NASA Ames Prognostics Center of Excellence. Obtained results demonstrate the improved accuracy and robustness of the proposed probabilistic fusion approach with respect to (i) a single BNN model and (ii) a classical stacking strategy based on different BNNs.