Braking control strategy of distributed electric vehicle based on vehicle velocity prediction

Meiying Li^¹, Chengxin Li^¹, Xuebo Li^², Shu Wang^¹, Xuan Zhao^¹

1School of Automobile, Chang’an University, Xi’an, Shaanxi 710000, China

2School of Mechanical and Electrical Engineering, Xi’an University of Architecture and Technology, Xi’an, Shaanxi 710000, China

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Abstract

To enhance the efficiency of braking energy recovery in distributed electric vehicles, this study investigates the impact of vehicle velocity prediction on braking performance. A regenerative braking control strategy that incorporates vehicle velocity prediction is proposed. Initially, a vehicle velocity prediction model is developed using a backpropagation neural network, which is trained under various operational conditions, and its validity is confirmed through testing. Subsequently, a braking control strategy that integrates vehicle velocity prediction is formulated based on a parallel braking control approach to optimize braking energy recovery. Finally, simulations of the proposed control strategy are conducted and compared with a strategy that does not utilize velocity prediction, under both joint working conditions and the Worldwide Harmonized Light Vehicles Test Cycle (WLTC). The findings indicate that the control strategy utilizing vehicle velocity prediction achieves greater energy recovery in both scenarios, with improvements in braking energy recovery efficiency of 9.2% and 6.13% over the non-predictive strategy, respectively. These results demonstrate the efficacy and rationale of the proposed approach.

Keywords

automotive engineering velocity prediction energy recovery control strategy

References

[1]

Zhang, X.D., Gohlich D. A novel driving and regenerative braking regulation design based on distributed drive electric vehicles[C]//2016 IEEE Vehicle Power and Propulsion Conference (VPPC). Hangzhou: IEEE, 2016.

Crossref

[2]

Zhang, J.Z., Lü, C., Gou, J.F., et al. Cooperative control of regenerative braking and hydraulic braking of an electrified passenger car[J]. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2012, 226(10): 1289–1302.

Crossref Google Scholar

[3]

Li, C.B., Yi, Q., Hu, R., et al. Control strategy for regenerative braking based on fuzzy pattern recognition indual-motor electric vehicles[J]. Computer Integrated Manufacturing Systems, 2020, 26(4): 871–881.

Google Scholar

[4]

Baker, D., Asher, Z., Bradley, T. Investigation of vehicle speed prediction from neural network fit of real world driving data for improved engine On/Off control of the EcoCAR3 hybrid Camaro[R]. SAE Technical Paper, 2017-01-1262, 2017.

Crossref

[5]

Yu, S.M., Lin, D., Sun, Z., et al. Efficient model predictive control for real-time energy optimization of battery-supercapacitors in electric vehicles[J]. International Journal of Energy Research, 2020, 44(9): 7495–7506.

Crossref Google Scholar

[6]

Wang, W.D., Guo, X.H., Yang, C., et al. A multi-objective optimization energy management strategy for power split HEV based on velocity prediction[J]. Energy, 2022, 238:121714.1-121714.14.

Crossref

[7]

Li, W.F., Du, H.P., Li, W.H. Four-wheel electric braking system configuration with new braking torque distribution strategy for improving energy recovery efficiency[J]. IEEE Transactions on Intelligent Transportation Systems, 2020, 21(1): 87–103.

Crossref Google Scholar

[8]

Suliman, A., Yun, Z. A review on back-propagation neural networks in the application of remote sensing image classification[J]. Journal of Earth Science and Engineering, 2015, 5(1): 52–65.

Crossref Google Scholar

Journal of Highway and Transportation Research and Development (English Edition)

Volume 18 Issue 4,
December 2024

Pages 67-77

DOI: 10.26599/HTRD.2024.9480029

Cite this article:

Li M, Li C, Li X, et al. Braking control strategy of distributed electric vehicle based on vehicle velocity prediction. Journal of Highway and Transportation Research and Development (English Edition), 2024, 18(4): 67-77. https://doi.org/10.26599/HTRD.2024.9480029