Local Distribution Voltage Control Using Large-Scale Coordinated PV Inverters: A Novel Multi-Agent Deep Reinforcement Learning-Based Approach

Yinfan Wang; Weihao Hu; Di Cao; Pengfei Zhao; Sayed Abulanwar; Zhe Chen; Frede Blaabjerg

doi:10.1109/TSG.2025.3533958

Local Distribution Voltage Control Using Large-Scale Coordinated PV Inverters: A Novel Multi-Agent Deep Reinforcement Learning-Based Approach

Yinfan Wang, Weihao Hu, Di Cao^*, Pengfei Zhao, Sayed Abulanwar, Zhe Chen, Frede Blaabjerg

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Abstract

This letter develops a novel multi-agent deep reinforcement learning (MADRL)-based local control method that can achieve coordinated scheduling of large-scale PV inverters using local information. This is achieved by the development of a system state inference-aided actor structure for each agent and implementation of random sequential updating within centralized-training-decentralized-execution framework. To enhance the coordination between agents utilizing local observation, a state latent inductive reasoning-based composite loss is further designed for the optimization of the inference models. Simulation tests on IEEE 123-node network demonstrate the superiority of the developed local control method when there is a large number of PV inverters.

Originalsprog	Engelsk
Tidsskrift	IEEE Transactions on Smart Grid
ISSN	1949-3053
DOI	https://doi.org/10.1109/TSG.2025.3533958
Status	Accepteret/In press - 2025

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Publisher Copyright:
© 2010-2012 IEEE.

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title = "Local Distribution Voltage Control Using Large-Scale Coordinated PV Inverters: A Novel Multi-Agent Deep Reinforcement Learning-Based Approach",

abstract = "This letter develops a novel multi-agent deep reinforcement learning (MADRL)-based local control method that can achieve coordinated scheduling of large-scale PV inverters using local information. This is achieved by the development of a system state inference-aided actor structure for each agent and implementation of random sequential updating within centralized-training-decentralized-execution framework. To enhance the coordination between agents utilizing local observation, a state latent inductive reasoning-based composite loss is further designed for the optimization of the inference models. Simulation tests on IEEE 123-node network demonstrate the superiority of the developed local control method when there is a large number of PV inverters.",

keywords = "Distribution voltage control, large-scale PV inverter, multi-agent deep reinforcement learning",

author = "Yinfan Wang and Weihao Hu and Di Cao and Pengfei Zhao and Sayed Abulanwar and Zhe Chen and Frede Blaabjerg",

note = "Publisher Copyright: {\textcopyright} 2010-2012 IEEE.",

year = "2025",

doi = "10.1109/TSG.2025.3533958",

language = "English",

journal = "IEEE Transactions on Smart Grid",

issn = "1949-3053",

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T1 - Local Distribution Voltage Control Using Large-Scale Coordinated PV Inverters

T2 - A Novel Multi-Agent Deep Reinforcement Learning-Based Approach

AU - Wang, Yinfan

AU - Hu, Weihao

AU - Cao, Di

AU - Zhao, Pengfei

AU - Abulanwar, Sayed

AU - Chen, Zhe

AU - Blaabjerg, Frede

PY - 2025

Y1 - 2025

N2 - This letter develops a novel multi-agent deep reinforcement learning (MADRL)-based local control method that can achieve coordinated scheduling of large-scale PV inverters using local information. This is achieved by the development of a system state inference-aided actor structure for each agent and implementation of random sequential updating within centralized-training-decentralized-execution framework. To enhance the coordination between agents utilizing local observation, a state latent inductive reasoning-based composite loss is further designed for the optimization of the inference models. Simulation tests on IEEE 123-node network demonstrate the superiority of the developed local control method when there is a large number of PV inverters.

AB - This letter develops a novel multi-agent deep reinforcement learning (MADRL)-based local control method that can achieve coordinated scheduling of large-scale PV inverters using local information. This is achieved by the development of a system state inference-aided actor structure for each agent and implementation of random sequential updating within centralized-training-decentralized-execution framework. To enhance the coordination between agents utilizing local observation, a state latent inductive reasoning-based composite loss is further designed for the optimization of the inference models. Simulation tests on IEEE 123-node network demonstrate the superiority of the developed local control method when there is a large number of PV inverters.

KW - Distribution voltage control

KW - large-scale PV inverter

KW - multi-agent deep reinforcement learning

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DO - 10.1109/TSG.2025.3533958

M3 - Journal article

AN - SCOPUS:85216365440

SN - 1949-3053

JO - IEEE Transactions on Smart Grid

JF - IEEE Transactions on Smart Grid

ER -

Local Distribution Voltage Control Using Large-Scale Coordinated PV Inverters: A Novel Multi-Agent Deep Reinforcement Learning-Based Approach

Abstract

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