A robust state-of-charge estimator for multiple types of lithium-ion batteries using adaptive extended Kalman filter

This paper presents a novel data-driven based approach for the estimation of the state of charge (SoC) of multiple types of lithium ion battery (LiB) cells with adaptive extended Kalman filter (AEKF). A modified second-order RC network based battery model is employed for the state estimation. Based on the battery model and experimental data, the SoC variation per mV voltage for different types of battery chemistry is analyzed and the parameters are identified. The AEKF algorithm is then employed to achieve accurate data-driven based SoC estimation, and the multi-parameter, closed loop feedback system is used to achieve robustness. The accuracy and convergence of the proposed approach is analyzed for different types of LiB cells, including convergence behavior of the model with a large initial SoC error. The results show that the proposed approach has good accuracy for different types of LiB cells, especially for C/LFP LiB cell that has a flat open circuit voltage (OCV) curve. The experimental results show good agreement with the estimation results with maximum error being less than 3%. •Proposed a dynamic universal battery model based on second-order RC network.•Proposed an AEKF-based SoC estimation approach with multiple closed loop feedback.•Developed a SOC estimator for suitable for multiple lithium ion battery chemistries.•Proved the system robustness and convergence behavior of SoC estimators.