Predictive-model-based dynamic coordination control strategy for power-split hybrid electric bus

Parameter-matching methods and optimal control strategies of the top-selling hybrid electric vehicle (HEV), namely, power-split HEV, are widely studied. In particular, extant research on control strategy focuses on the steady-state energy management strategy to obtain better fuel economy. However, g...

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Bibliographic Details
Published in:Mechanical systems and signal processing 2015-08, Vol.60-61, p.785-798
Main Authors: Zeng, Xiaohua, Yang, Nannan, Wang, Junnian, Song, Dafeng, Zhang, Nong, Shang, Mingli, Liu, Jianxin
Format: Article
Language:English
Subjects:
Algorithms
Buses (vehicles)
Comfort
Dynamic coordination
Dynamics
Engine torque estimation
Feedback control
Hybrid electric bus
Hybrid vehicles
Mathematical models
Predictive model
Riding
Strategy
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Summary:Parameter-matching methods and optimal control strategies of the top-selling hybrid electric vehicle (HEV), namely, power-split HEV, are widely studied. In particular, extant research on control strategy focuses on the steady-state energy management strategy to obtain better fuel economy. However, given that multi-power sources are highly coupled in power-split HEVs and influence one another during mode shifting, conducting research on dynamic coordination control strategy (DCCS) to achieve riding comfort is also important. This paper proposes a predictive-model-based DCCS. First, the dynamic model of the objective power-split HEV is built and the mode shifting process is analyzed based on the developed model to determine the reason for the system shock generated. Engine torque estimation algorithm is then designed according to the principle of the nonlinear observer, and the prediction model of the degree of shock is established based on the theory of model predictive control. Finally, the DCCS with adaptation for a complex driving cycle is realized by combining the feedback control and the predictive model. The presented DCCS is validated on the co-simulation platform of AMESim and Simulink. Results show that the shock during mode shifting is well controlled, thereby improving riding comfort. •This paper proposes a predictive model based dynamic coordination control strategy.•The dynamic model of the power-split hybrid electric bus is built.•An engine estimation algorithm is designed for the control strategy.•Co-simulation results verify that smooth mode shifting is realized.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2014.12.016