Abstract
To achieve the real-time application of a dynamic programming (DP) control strategy, we propose a predictive energy management strategy (PEMS) based on full-factor trip information, including vehicle speed, slip ratio and slope. Firstly, the prediction model of the full-factor trip information is proposed, which provides an information basis for global optimization energy management. To improve the prediction’s accuracy, the vehicle speed is predicted based on the state transition probability matrix generated in the same driving scene. The characteristic parameters are extracted by a feature selection method taken as the basis for the driving condition’s identification. Similar to speed prediction, regarding the uncertain route at an intersection, the slope prediction is modelled as a Markov model. On the basis of the predicted speed and the identified maximum adhesion coefficient, the slip ratio is predicted based on a neural network. Then, a predictive energy management strategy is developed based on the predictive full-factor trip information. According to the statistical rules of DP results under multiple standard driving cycles, the reference SOC trajectory is generated to ensure global sub-optimality, which determines the feasible state domain at each prediction horizon. Simulations are performed under different types of driving conditions (Urban Dynamometer Driving Schedule, UDDS and World Light Vehicle Test Cycle, WLTC) to verify the effectiveness of the proposed strategy.
Highlights
To cope with the problem of individual energy shortages and environmental pollution, developing new energy vehicles (NEVs) is an inevitable choice for the global automotive industry in the 21st century [1]
The Prediction Model of Slip Ratio Based on Back Propagation (BP) Neural Network
By analyzing the change trend of the optimal state of charge (SOC) trajectory, we found that the optimal SOC trajectory obtained by the dynamic programming (DP) strategy declines linearly as a whole
Summary
To cope with the problem of individual energy shortages and environmental pollution, developing new energy vehicles (NEVs) is an inevitable choice for the global automotive industry in the 21st century [1]. As the main trip information, has a significant impact on global optimization energy management. By considering the impact of road gradient on the driving demand of the vehicle, a plug-in hybrid electric vehicle energy management strategy based on road gradient information is proposed in reference [20]. Based on the predictive trip information, optimization in a short-term horizon can be achieved, which can significantly improve the real-time performance of the DP strategy. Based on full-factor trip information, including vehicle speed, slope and slip ratio. A predictive energy management strategy (PEMS) is developed, which generates a reference SOC trajectory to ensure global optimality.
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