Related papers: Simple statistical models and sequential deep learning for Lithium-ion batteries degradation under dynamic conditions: Fractional Polynomials vs Neural Networks

Simple statistical models and sequential deep learning for Lithium-ion batteries degradation under dynamic conditions: Fractional Polynomials vs Neural Networks

URL: http://arxiv.org/abs/2102.08111v1
Date: Tue, 16 Feb 2021 12:26:23 GMT
Title: Simple statistical models and sequential deep learning for Lithium-ion batteries degradation under dynamic conditions: Fractional Polynomials vs Neural Networks
Authors: Clara B. Salucci, Azzeddine Bakdi, Ingrid K. Glad, Erik Vanem, Riccardo De Bin
Abstract summary: Longevity and safety of Lithium-ion batteries are facilitated by efficient monitoring and adjustment of the battery operating conditions. It is crucial to implement fast and accurate algorithms for State of Health (SoH) monitoring on the Battery Management System. This paper proposes and compares two data-driven approaches: a Long Short-Term Memory neural network, and a Multivariable Fractional Polynomial regression.
Score: 1.8899300124593648
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Longevity and safety of Lithium-ion batteries are facilitated by efficient monitoring and adjustment of the battery operating conditions: hence, it is crucial to implement fast and accurate algorithms for State of Health (SoH) monitoring on the Battery Management System. The task is challenging due to the complexity and multitude of the factors contributing to the battery capacity degradation, especially because the different degradation processes occur at various timescales and their interactions play an important role. This paper proposes and compares two data-driven approaches: a Long Short-Term Memory neural network, from the field of deep learning, and a Multivariable Fractional Polynomial regression, from classical statistics. Models from both classes are trained from historical data of one exhausted cell and used to predict the SoH of other cells. This work uses data provided by the NASA Ames Prognostics Center of Excellence, characterised by varying loads which simulate dynamic operating conditions. Two hypothetical scenarios are considered: one assumes that a recent true capacity measurement is known, the other relies solely on the cell nominal capacity. Both methods are effective, with low prediction errors, and the advantages of one over the other in terms of interpretability and complexity are discussed in a critical way.

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