Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion

This paper aims to answer how to effectively integrate the data-driven method into the traditional predictive energy management algorithm rather than replacing it outright. Given the challenge of selecting an appropriate prediction horizon for predictive energy management, this study seeks to bridge...

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Main Authors:	Li, Menglin, Liu, Haoran, Yan, Mei, Wu, Jingda, Jin, Lisheng, He, Hongwen
Other Authors:	School of Mechanical and Aerospace Engineering
Format:	Article
Language:	English
Published:	2024
Subjects:	Engineering Energy Management Fuel Cell Buses
Online Access:	https://hdl.handle.net/10356/173532
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Institution:	Nanyang Technological University
Language:	English

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spelling	sg-ntu-dr.10356-1735322024-02-17T16:48:48Z Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion Li, Menglin Liu, Haoran Yan, Mei Wu, Jingda Jin, Lisheng He, Hongwen School of Mechanical and Aerospace Engineering Engineering Energy Management Fuel Cell Buses This paper aims to answer how to effectively integrate the data-driven method into the traditional predictive energy management algorithm rather than replacing it outright. Given the challenge of selecting an appropriate prediction horizon for predictive energy management, this study seeks to bridge traditional predictive energy management with machine learning approaches, thereby presenting a novel bi-level predictive energy management strategy for fuel cell buses with multi-prediction horizons. In the upper layer, the core parameter, prediction horizon, of the traditional model predictive control energy management framework is optimized using two distinct data-driven methods. The first method employs deep learning to establish a mapping relationship between the vehicle states and the optimal prediction horizon through deep neural networks. The second method utilizes reinforcement learning to obtain the best prediction horizon under varying vehicle states through intelligent agent exploration. In the lower level, predictive energy management is performed on fuel cell buses based on optimization levels. Finally, the proposed strategy is validated using test data from actual fuel cell buses. The results demonstrate that two data-driven methods, based on the optimal ΔSoC approximation and the deep reinforcement learning, can select the appropriate prediction horizon more conducive to energy saving according to the vehicle states. Regarding energy consumption, the multi-horizon predictive energy management based on deep reinforcement learning exhibits a remarkable reduction in energy consumption by 7.62 %, 4.55 %, 4.60 %, and 7.80 %, when compared with the predictive energy management employing fixed prediction horizons of 5 s, 10 s, 15 s, and 20 s, respectively. Furthermore, it outperforms the multi-horizon predictive energy management approach based on the optimal ΔSoC approximation by 3.59 %. Published version This work is supported by the National Natural Science Foundation of China (Grand No. 52202484), the Hebei Natural Science Foundation (Grand Nos. F2021203118, E2020203174), the Beijing Natural Science Foundation (Grand No. J210007) and the Science and Technology Project of Hebei Education Department (Grand No. QN2022093). 2024-02-13T02:41:23Z 2024-02-13T02:41:23Z 2023 Journal Article Li, M., Liu, H., Yan, M., Wu, J., Jin, L. & He, H. (2023). Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion. Energy Conversion and Management: X, 20, 100414-. https://dx.doi.org/10.1016/j.ecmx.2023.100414 2590-1745 https://hdl.handle.net/10356/173532 10.1016/j.ecmx.2023.100414 2-s2.0-85163940161 20 100414 en Energy Conversion and Management: X © 2023 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/bync-nd/4.0/). application/pdf
institution	Nanyang Technological University
building	NTU Library
continent	Asia
country	Singapore Singapore
content_provider	NTU Library
collection	DR-NTU
language	English
topic	Engineering Energy Management Fuel Cell Buses
spellingShingle	Engineering Energy Management Fuel Cell Buses Li, Menglin Liu, Haoran Yan, Mei Wu, Jingda Jin, Lisheng He, Hongwen Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
description	This paper aims to answer how to effectively integrate the data-driven method into the traditional predictive energy management algorithm rather than replacing it outright. Given the challenge of selecting an appropriate prediction horizon for predictive energy management, this study seeks to bridge traditional predictive energy management with machine learning approaches, thereby presenting a novel bi-level predictive energy management strategy for fuel cell buses with multi-prediction horizons. In the upper layer, the core parameter, prediction horizon, of the traditional model predictive control energy management framework is optimized using two distinct data-driven methods. The first method employs deep learning to establish a mapping relationship between the vehicle states and the optimal prediction horizon through deep neural networks. The second method utilizes reinforcement learning to obtain the best prediction horizon under varying vehicle states through intelligent agent exploration. In the lower level, predictive energy management is performed on fuel cell buses based on optimization levels. Finally, the proposed strategy is validated using test data from actual fuel cell buses. The results demonstrate that two data-driven methods, based on the optimal ΔSoC approximation and the deep reinforcement learning, can select the appropriate prediction horizon more conducive to energy saving according to the vehicle states. Regarding energy consumption, the multi-horizon predictive energy management based on deep reinforcement learning exhibits a remarkable reduction in energy consumption by 7.62 %, 4.55 %, 4.60 %, and 7.80 %, when compared with the predictive energy management employing fixed prediction horizons of 5 s, 10 s, 15 s, and 20 s, respectively. Furthermore, it outperforms the multi-horizon predictive energy management approach based on the optimal ΔSoC approximation by 3.59 %.
author2	School of Mechanical and Aerospace Engineering
author_facet	School of Mechanical and Aerospace Engineering Li, Menglin Liu, Haoran Yan, Mei Wu, Jingda Jin, Lisheng He, Hongwen
format	Article
author	Li, Menglin Liu, Haoran Yan, Mei Wu, Jingda Jin, Lisheng He, Hongwen
author_sort	Li, Menglin
title	Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
title_short	Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
title_full	Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
title_fullStr	Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
title_full_unstemmed	Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
title_sort	data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion
publishDate	2024
url	https://hdl.handle.net/10356/173532
_version_	1794549346150121472

Data-driven bi-level predictive energy management strategy for fuel cell buses with algorithmics fusion

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