Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft

Yu Zeng; Ziheng Xiao; Qingxiang Liu; Gaowen Liang; Ezequiel Rodriguez; Guibin Zou; Xin Zhang; Josep Pou

doi:10.1109/TTE.2024.3514657

Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft

Yu Zeng, Ziheng Xiao^*, Qingxiang Liu^*, Gaowen Liang, Ezequiel Rodriguez, Guibin Zou, Xin Zhang, Josep Pou

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

This article proposes a physics-informed deep transfer reinforcement learning (PIDTRL) approach for power balance control and triple phase shift (TPS) modulation method for the input-series output-parallel dual active bridge (ISOP-DAB) converter-based auxiliary power module (APM) in electric aircraft. The approach involves three stages: 1) centralized training of deep reinforcement learning agents to balance power and reduce current stress in the ISOP-DAB converter; 2) effective knowledge transfer from a source simulation system to a target experimental system using minimal experimental data, providing a scalable solution without extensive data reliance; and 3) deployment of multiple agents for online control in the ISOP-DAB converter. The proposed method adaptively determines optimal modulation variables (duty cycles and phase shifts) in stochastic and uncertain environments without requiring accurate model information. The experimental results validate the effectiveness of the proposed PIDTRL algorithm.

Original language	English
Pages (from-to)	6629-6639
Number of pages	11
Journal	IEEE Transactions on Transportation Electrification
Volume	11
Issue number	2
DOIs	https://doi.org/10.1109/TTE.2024.3514657
Publication status	Published - 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 IEEE.

ASJC Scopus Subject Areas

Automotive Engineering
Transportation
Energy Engineering and Power Technology
Electrical and Electronic Engineering

Keywords

Auxiliary power module (APM)
input-series output-parallel dual active bridge (ISOP-DAB) converter
physics-informed deep transfer reinforcement learning (PIDTRL)
triple phase shift (TPS) modulation

Access to Document

10.1109/TTE.2024.3514657

Cite this

Zeng, Y., Xiao, Z., Liu, Q., Liang, G., Rodriguez, E., Zou, G., Zhang, X., & Pou, J. (2025). Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft. IEEE Transactions on Transportation Electrification, 11(2), 6629-6639. https://doi.org/10.1109/TTE.2024.3514657

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title = "Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft",

abstract = "This article proposes a physics-informed deep transfer reinforcement learning (PIDTRL) approach for power balance control and triple phase shift (TPS) modulation method for the input-series output-parallel dual active bridge (ISOP-DAB) converter-based auxiliary power module (APM) in electric aircraft. The approach involves three stages: 1) centralized training of deep reinforcement learning agents to balance power and reduce current stress in the ISOP-DAB converter; 2) effective knowledge transfer from a source simulation system to a target experimental system using minimal experimental data, providing a scalable solution without extensive data reliance; and 3) deployment of multiple agents for online control in the ISOP-DAB converter. The proposed method adaptively determines optimal modulation variables (duty cycles and phase shifts) in stochastic and uncertain environments without requiring accurate model information. The experimental results validate the effectiveness of the proposed PIDTRL algorithm.",

keywords = "Auxiliary power module (APM), input-series output-parallel dual active bridge (ISOP-DAB) converter, physics-informed deep transfer reinforcement learning (PIDTRL), triple phase shift (TPS) modulation",

author = "Yu Zeng and Ziheng Xiao and Qingxiang Liu and Gaowen Liang and Ezequiel Rodriguez and Guibin Zou and Xin Zhang and Josep Pou",

note = "Publisher Copyright: {\textcopyright} 2024 IEEE.",

year = "2025",

doi = "10.1109/TTE.2024.3514657",

language = "English",

volume = "11",

pages = "6629--6639",

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Zeng, Y, Xiao, Z, Liu, Q, Liang, G, Rodriguez, E, Zou, G, Zhang, X & Pou, J 2025, 'Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft', IEEE Transactions on Transportation Electrification, vol. 11, no. 2, pp. 6629-6639. https://doi.org/10.1109/TTE.2024.3514657

Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft. / Zeng, Yu; Xiao, Ziheng; Liu, Qingxiang et al.
In: IEEE Transactions on Transportation Electrification, Vol. 11, No. 2, 2025, p. 6629-6639.

Research output: Contribution to journal › Article › peer-review

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AU - Zeng, Yu

AU - Xiao, Ziheng

AU - Liu, Qingxiang

AU - Liang, Gaowen

AU - Rodriguez, Ezequiel

AU - Zou, Guibin

AU - Zhang, Xin

AU - Pou, Josep

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N2 - This article proposes a physics-informed deep transfer reinforcement learning (PIDTRL) approach for power balance control and triple phase shift (TPS) modulation method for the input-series output-parallel dual active bridge (ISOP-DAB) converter-based auxiliary power module (APM) in electric aircraft. The approach involves three stages: 1) centralized training of deep reinforcement learning agents to balance power and reduce current stress in the ISOP-DAB converter; 2) effective knowledge transfer from a source simulation system to a target experimental system using minimal experimental data, providing a scalable solution without extensive data reliance; and 3) deployment of multiple agents for online control in the ISOP-DAB converter. The proposed method adaptively determines optimal modulation variables (duty cycles and phase shifts) in stochastic and uncertain environments without requiring accurate model information. The experimental results validate the effectiveness of the proposed PIDTRL algorithm.

AB - This article proposes a physics-informed deep transfer reinforcement learning (PIDTRL) approach for power balance control and triple phase shift (TPS) modulation method for the input-series output-parallel dual active bridge (ISOP-DAB) converter-based auxiliary power module (APM) in electric aircraft. The approach involves three stages: 1) centralized training of deep reinforcement learning agents to balance power and reduce current stress in the ISOP-DAB converter; 2) effective knowledge transfer from a source simulation system to a target experimental system using minimal experimental data, providing a scalable solution without extensive data reliance; and 3) deployment of multiple agents for online control in the ISOP-DAB converter. The proposed method adaptively determines optimal modulation variables (duty cycles and phase shifts) in stochastic and uncertain environments without requiring accurate model information. The experimental results validate the effectiveness of the proposed PIDTRL algorithm.

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Physics-Informed Deep Transfer Reinforcement Learning Method for the Input-Series Output-Parallel Dual Active Bridge-Based Auxiliary Power Modules in Electrical Aircraft

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

Access to Document

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