Bayesian Model Selection of Lithium-Ion Battery Models via Bayesian Quadrature
This work addresses model selection challenges for researchers and engineers in battery modeling, offering a more reliable and efficient method, though it is incremental as it applies existing Bayesian techniques to a specific domain.
The paper tackled the problem of selecting the best lithium-ion battery model from many options by using Bayesian model selection with Bayesian quadrature, which efficiently computes model evidence to choose the simplest accurate model and outperforms traditional criteria like RMSE and BIC in cases with multimodal posteriors, while also providing faster computation than Monte Carlo methods.
A wide variety of battery models are available, and it is not always obvious which model `best' describes a dataset. This paper presents a Bayesian model selection approach using Bayesian quadrature. The model evidence is adopted as the selection metric, choosing the simplest model that describes the data, in the spirit of Occam's razor. However, estimating this requires integral computations over parameter space, which is usually prohibitively expensive. Bayesian quadrature offers sample-efficient integration via model-based inference that minimises the number of battery model evaluations. The posterior distribution of model parameters can also be inferred as a byproduct without further computation. Here, the simplest lithium-ion battery models, equivalent circuit models, were used to analyse the sensitivity of the selection criterion to given different datasets and model configurations. We show that popular model selection criteria, such as root-mean-square error and Bayesian information criterion, can fail to select a parsimonious model in the case of a multimodal posterior. The model evidence can spot the optimal model in such cases, simultaneously providing the variance of the evidence inference itself as an indication of confidence. We also show that Bayesian quadrature can compute the evidence faster than popular Monte Carlo based solvers.