Machines, Vol. 13, Pages 799: Dual Modal Intelligent Optimization BP Neural Network Model Integrating Aquila Optimizer and African Vulture Optimization Algorithm and Its Application in Lithium-Ion Battery SOH Prediction


Machines, Vol. 13, Pages 799: Dual Modal Intelligent Optimization BP Neural Network Model Integrating Aquila Optimizer and African Vulture Optimization Algorithm and Its Application in Lithium-Ion Battery SOH Prediction

Machines doi: 10.3390/machines13090799

Authors:
Xingxing Wang
Shun Liang
Junyi Li
Hongjun Ni
Yu Zhu
Shuaishuai Lv
Linfei Chen

To enhance the accuracy and robustness of lithium-ion battery state-of-health (SOH) prediction, this study proposes a dual-mode intelligent optimization BP neural network model (AO–AVOA–BP) which integrates the Aquila Optimizer (AO) and the African Vulture Optimization Algorithm (AVOA). The model leverages the global search capabilities of AO and the local exploitation strengths of AVOA to achieve efficient and collaborative optimization of network parameters. In terms of feature construction, eight key health indicators are extracted from voltage, current, and temperature signals during the charging phase, and the optimal input set is selected using gray relational analysis. Experimental results demonstrate that the AO–AVOA–BP model significantly outperforms traditional BP and other improved models on both the NASA and CALCE datasets, with MAE, RMSE, and MAPE maintained within 0.0087, 0.0115, and 1.095%, respectively, indicating outstanding prediction accuracy and strong generalization performance. The proposed method demonstrates strong generalization capability and engineering adaptability, providing reliable support for lifetime prediction and safety warning in battery management systems (BMS). Moreover, it shows great potential for wide application in the health management of electric vehicles and energy storage systems.



Source link

Xingxing Wang www.mdpi.com