2026-04-07T11:47:15Zhttps://ebiltegia.mondragon.edu/oai/requestoai:ebiltegia.mondragon.edu:20.500.11984/140002026-01-29T08:38:23Zcom_20.500.11984_1143col_20.500.11984_1148
00925njm 22002777a 4500
dc
Yeregui, Josu
author
Etxeberria, Malen
author
GARAYALDE, ERIK
author
IRAOLA, UNAI
author
2025
The accurate on-site estimation of battery electrochemical parameters is crucial for optimal battery
management, enabling advanced control strategies and reliable prognostics. However, physics-based
methods often suffer from high computational costs, require specific testing setups; while data driven
solutions lack interpretability, creating a need for solutions including the benefits of both strategies [1].
We present a novel framework for on-site physical parameter estimation, for real-time characterization
of lithium-ion batteries, leveraging on the recent attention for hybrid physics-based and data-driven
solutions. Our approach utilizes a two-phase modelling strategy that combines Physics-Informed Neural
Networks (PINNs) with transfer learning [2]. In an initial ”data-agnostic” phase, a PINN is trained
exclusively using the governing physical equations of a single particle model. The model is set to include
Fourier Feature transformations on the dependent variables, so that we extend the learning range to
dynamic current profiles. During the second phase, critical ageing-related electrochemical parameters are
fine-tuned using real-world voltage profile data.
This two-phase strategy significantly reduces computational cost compared to traditional optimization
methods, making it suitable for implementation on Battery Management Systems, and the dataagnosticism
of the initial training phase avoids the need for large chunks of data. We demonstrated the
framework’s efficacy through the estimation of diffusivities and active material volume fractions. Experimental
and analytical validations showed a relative accuracy of 3.89% in estimating the active material
volume fractions. Furthermore, our proposed PINN-based approach outperformed classical optimization
techniques in accurately recovering parameters under varied ageing conditions.
https://katalogoa.mondragon.edu/janium-bin/janium_login_opac.pl?find&ficha_no=200508
https://hdl.handle.net/20.500.11984/14000
ODS 7 Energía asequible y no contaminante
ODS 9 Industria, innovación e infraestructura
ODS 11 Ciudades y comunidades sostenibles
On-site estimation of battery electrochemical parameters with physics-informed neural networks in dynamic current profiles