A novel torque distribution strategy based on deep recurrent neural network for parallel hybrid electric vehicle

H. Kong; Y. Fang; L. Fan; H. Wang; X. Zhang; J. Hu

doi:10.1109/ACCESS.2019.2917545

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A novel torque distribution strategy based on deep recurrent neural network for parallel hybrid electric vehicle

Journal article

Peer reviewed

A novel torque distribution strategy based on deep recurrent neural network for parallel hybrid electric vehicle

H. Kong, Y. Fang, L. Fan, H. Wang, X. Zhang and J. Hu

IEEE Access, Vol.7, pp.65174-65185

2019

DOI: https://doi.org/10.1109/ACCESS.2019.2917545

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Abstract

In this paper, energy management strategy (EMS) model based on deep recurrent neural network (DRNN) is presented to learn optimal torque distribution for the single-axle parallel hybrid electric vehicle. The model has two distinguishing properties: 1) because the EMS is formulated as a time series prediction problem, taking historical data as input of the EMS model captures the input-and-output dynamic characteristics and enhances the prediction capability and 2) the EMS model based on end-to-end framework directly generates torque distribution results without extracting features of driving cycles and other artificial interference. The extensive simulations are conducted to demonstrate the accuracy and generalization capability of the EMS model in public platform TensorFlow. Comparing with other energy management strategies, our proposed model yields better performance in terms of fuel economy and accuracy. The simulation results show that our proposed EMS model provides a novel way to study the energy management strategy.

Details

Title: A novel torque distribution strategy based on deep recurrent neural network for parallel hybrid electric vehicle
Authors/Creators: H. Kong (Author/Creator)
Y. Fang (Author/Creator)
L. Fan (Author/Creator)
H. Wang (Author/Creator)
X. Zhang (Author/Creator)
J. Hu (Author/Creator)
Publication Details: IEEE Access, Vol.7, pp.65174-65185
Publisher: IEEE
Identifiers: 991005541670907891
Copyright: © Copyright 2019 IEEE
Murdoch Affiliation: School of Engineering and Information Technology
Language: English
Resource Type: Journal article

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Collaboration types: Domestic collaboration; International collaboration
Citation topics: 4 Electrical Engineering, Electronics & Computer Science; 4.18 Power Systems & Electric Vehicles; 4.18.788 Electric Vehicles
Web Of Science research areas: Computer Science, Information Systems; Engineering, Electrical & Electronic; Telecommunications
ESI research areas: Engineering