Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach

Daniel Pesantez; Oswaldo Menendez; H. Renaudineau; S. Kouro; S. Rivera; Jose Rodriguez

doi:10.1109/ICA-ACCA62622.2024.10766834

Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach

Daniel Pesantez^*, Oswaldo Menendez, H. Renaudineau, S. Kouro, S. Rivera, Jose Rodriguez

^*Corresponding author for this work

DC systems, Energy conversion & Storage

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

Abstract

In recent years, the electric vehicle (EV) industry has experienced significant advancements, simultaneously driving substantial progress in battery technology. The evolution of battery systems necessitates enhancements in charging infrastructure to attain elevated power levels during the charging process, thereby minimizing charging time. Various algorithms have been developed for driving battery charging; however, these algorithms necessitate the creation of diverse controllers to generate precise trigger signals for the semiconductors within the various power converters utilized in charging stations. This work presents the design of an innovative model-free control system for Type I impedance network Partial Power Converter (PPC) in which a Deep Reinforcement Learning (DRL) agent generates control signals during the different charging stages. Particularly, a Twin-Delayed Deep Deterministic Policy Gradient (TD3) algorithm is used to substitute the inner control loop of traditional control systems. To this end, different agents were designed, trained, and tested inside a built simulation environment. It is worth noting that TD3-based control allows for the optimal functionality of a type I impedance network PPC within the context of EV battery charging applications, according to the specified CC-CV charging algorithm. Empirical results revealed that the battery system reached an 80% state of charge in under 8 minutes starting from an initial 20%.

Original language	English
Title of host publication	2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024
Publisher	IEEE
ISBN (Electronic)	9798350378115
DOIs	https://doi.org/10.1109/ICA-ACCA62622.2024.10766834
Publication status	Published - 2024
Event	2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024 - Santiago, Chile Duration: 20 Oct 2024 → 23 Oct 2024

Publication series

Name	2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024

Conference

Conference	2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024
Country/Territory	Chile
City	Santiago
Period	20/10/24 → 23/10/24

Bibliographical note

Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care
Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.

Keywords

artificial intelligence
deep reinforcement learning
electric vehicles
neural network
partial power converter

Access to Document

10.1109/ICA-ACCA62622.2024.10766834

Cite this

Pesantez, D., Menendez, O., Renaudineau, H., Kouro, S., Rivera, S., & Rodriguez, J. (2024). Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach. In 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024 (2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024). IEEE. https://doi.org/10.1109/ICA-ACCA62622.2024.10766834

Pesantez, Daniel ; Menendez, Oswaldo ; Renaudineau, H. et al. / Intelligent Control for Type I Partial Power Converters in EV Charging Systems : Twin-Delayed Deep Deterministic Policy Gradient Approach. 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024. IEEE, 2024. (2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024).

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title = "Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach",

abstract = "In recent years, the electric vehicle (EV) industry has experienced significant advancements, simultaneously driving substantial progress in battery technology. The evolution of battery systems necessitates enhancements in charging infrastructure to attain elevated power levels during the charging process, thereby minimizing charging time. Various algorithms have been developed for driving battery charging; however, these algorithms necessitate the creation of diverse controllers to generate precise trigger signals for the semiconductors within the various power converters utilized in charging stations. This work presents the design of an innovative model-free control system for Type I impedance network Partial Power Converter (PPC) in which a Deep Reinforcement Learning (DRL) agent generates control signals during the different charging stages. Particularly, a Twin-Delayed Deep Deterministic Policy Gradient (TD3) algorithm is used to substitute the inner control loop of traditional control systems. To this end, different agents were designed, trained, and tested inside a built simulation environment. It is worth noting that TD3-based control allows for the optimal functionality of a type I impedance network PPC within the context of EV battery charging applications, according to the specified CC-CV charging algorithm. Empirical results revealed that the battery system reached an 80% state of charge in under 8 minutes starting from an initial 20%.",

keywords = "artificial intelligence, deep reinforcement learning, electric vehicles, neural network, partial power converter",

author = "Daniel Pesantez and Oswaldo Menendez and H. Renaudineau and S. Kouro and S. Rivera and Jose Rodriguez",

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Pesantez, D, Menendez, O, Renaudineau, H, Kouro, S, Rivera, S & Rodriguez, J 2024, Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach. in 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024. 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024, IEEE, 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024, Santiago, Chile, 20/10/24. https://doi.org/10.1109/ICA-ACCA62622.2024.10766834

Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach. / Pesantez, Daniel; Menendez, Oswaldo; Renaudineau, H. et al.
2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024. IEEE, 2024. (2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024).

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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AU - Menendez, Oswaldo

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AU - Rivera, S.

AU - Rodriguez, Jose

N1 - Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.

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AB - In recent years, the electric vehicle (EV) industry has experienced significant advancements, simultaneously driving substantial progress in battery technology. The evolution of battery systems necessitates enhancements in charging infrastructure to attain elevated power levels during the charging process, thereby minimizing charging time. Various algorithms have been developed for driving battery charging; however, these algorithms necessitate the creation of diverse controllers to generate precise trigger signals for the semiconductors within the various power converters utilized in charging stations. This work presents the design of an innovative model-free control system for Type I impedance network Partial Power Converter (PPC) in which a Deep Reinforcement Learning (DRL) agent generates control signals during the different charging stages. Particularly, a Twin-Delayed Deep Deterministic Policy Gradient (TD3) algorithm is used to substitute the inner control loop of traditional control systems. To this end, different agents were designed, trained, and tested inside a built simulation environment. It is worth noting that TD3-based control allows for the optimal functionality of a type I impedance network PPC within the context of EV battery charging applications, according to the specified CC-CV charging algorithm. Empirical results revealed that the battery system reached an 80% state of charge in under 8 minutes starting from an initial 20%.

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Pesantez D, Menendez O, Renaudineau H, Kouro S, Rivera S, Rodriguez J. Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach. In 2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024. IEEE. 2024. (2024 IEEE International Conference on Automation/26th Congress of the Chilean Association of Automatic Control, ICA-ACCA 2024). doi: 10.1109/ICA-ACCA62622.2024.10766834

Intelligent Control for Type I Partial Power Converters in EV Charging Systems: Twin-Delayed Deep Deterministic Policy Gradient Approach

Abstract

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