Cooperative game-based solution for power system dynamic economic dispatch considering uncertainties: A case study of large-scale 5G base stations as virtual power plant

The uncertainty of renewable energy necessitates reliable demand response (DR) resources for power system auxiliary regulation. Meanwhile, the widespread deployment of energy-consuming 5G base stations (gNBs) drives internet service providers (ISPs) to seek energy expenses reduction. This paper inte...

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Bibliographic Details
Published in:Applied energy 2024-08, Vol.368, p.123463, Article 123463
Main Authors: Bao, Peng, Xu, Qingshan, Yang, Yongbiao, Zhao, Xianqiu
Format: Article
Language:English
Subjects:
5G base station
BESS
DED
Game theory
VPP
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Summary:The uncertainty of renewable energy necessitates reliable demand response (DR) resources for power system auxiliary regulation. Meanwhile, the widespread deployment of energy-consuming 5G base stations (gNBs) drives internet service providers (ISPs) to seek energy expenses reduction. This paper intelligently addresses these two complementary needs by integrating gNBs into the power system dynamic economic dispatch (DED). To achieve this, a combined DED model that incorporates both the power system and 5G communication network is developed, where numerous distributed gNBs and their backup energy storage systems (BESSs) are integrated as a virtual power plant (VPP) to offer power support and obtain economic incentives. Instead of traditional optimization methods, the combined DED model is solved by a cooperative game-based solution method in a benefit-balanced manner, facilitating the power system and 5G network to achieve a win-win DED solution. This method comprises a two-stage game model and a solution algorithm based on improved random drift particle swarm optimization (RDPSO). The improved RDPSO constructs an uncertainty set in each iteration, facilitating its solution of stochastic optimization involving power system uncertainties. Lastly, a VPP management function is developed within the 5G core network (5GC) to efficiently evaluate the VPP’s dispatchable capacity and formulate optimal control policies that can minimize control costs. Simulations based on the IEEE 118-bus system and real device data demonstrate that the proposed method can simultaneously reduce the power system’s operating costs and increase the ISP’s economic revenue. •Addressing complementary needs by integrating gNBs into power system DED.•Game-based solution for DED balancing supply and demand sides benefits.•Improved RDPSO algorithm for power system DED considering uncertainties.•VPP function efficiently evaluating dispatchable capacity and formulating optimal control policy.•Economic and technical win-win results in simulation based on real data.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2024.123463