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Accurately predicting the State of Health (SoH) of Lithium-ion Batteries (LIBs) is critical for improving Electric Vehicle (EV) performance and enabling smarter charging strategies, yet existing methods often struggle with variable cycle data and the limitations of physical models in capturing the complex behaviour of LIBs. To overcome these challenges, the present work introduces a hybrid deep learning framework, the Optuna-Optimised Convolutional Neural Network and Stacked Long Short-Term Memory (OptiCNN-SLSTM) model, which combines a 1D CNN for temporal feature compression with a stateful LSTM to capture both inter- and intra-sample dependencies. A two-step hyperparameter optimisation process is applied, first exploring different parameter sets and then refining them through Optuna optimisation. The model was trained and tested on the NASA and Oxford datasets and validated on a real-world EV E-kart battery dataset, achieving strong accuracy with RMSE values of 2.15% (B0005) and 2.18% (B0007) on NASA, 0.67% (cell-1) and 1.02% (cell-2) on Oxford, and exceptionally low errors on the E-kart dataset (MSE = 0.001%, RMSE = 0.03%, MAE = 0.28%), demonstrating its robustness and generalisability for practical EV battery health estimation.
Singh et al. (Sat,) studied this question.
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