Multi-commodity Optimization of Peer-to-peer Energy Trading Resources in Smart Grid

Olamide Jogunola; Bamidele Adebisi; Kelvin Anoh; Augustine Ikpehai; Mohammad Hammoudeh; Georgina Harris

doi:10.35833/MPCE.2020.000136

Multi-commodity Optimization of Peer-to-peer Energy Trading Resources in Smart Grid

Olamide Jogunola
, Bamidele Adebisi^*
, Kelvin Anoh
, Augustine Ikpehai
, Mohammad Hammoudeh
, Georgina Harris

^*Corresponding author for this work

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

21 Scopus citations

Abstract

Utility maximization is a major priority of prosumers participating in peer-to-peer energy trading and sharing (P2P-ETS). However, as more distributed energy resources integrate into the distribution network, the impact of the communication link becomes significant. We present a multi-commodity formulation that allows the dual-optimization of energy and communication resources in P2P-ETS. On one hand, the proposed algorithm minimizes the cost of energy generation and communication delay. On the other hand, it also maximizes the global utility of prosumers with fair resource allocation. We evaluate the algorithm in a variety of realistic conditions including a time-varying communication network with signal delay signal loss. The results show that the convergence is achieved in a fewer number of time steps than the previously proposed algorithms. It is further observed that the entities with a higher willingness to trade the energy acquire more satisfactions than others.

Original language	English
Pages (from-to)	29-39
Number of pages	11
Journal	Journal of Modern Power Systems and Clean Energy
Volume	10
Issue number	1
DOIs	https://doi.org/10.35833/MPCE.2020.000136
State	Published - 1 Jan 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2013 State Grid Electric Power Research Institute.

Keywords

Distributed algorithm
distributed dual-gradient (DDG)
economic dispatch
multi-commodity networks
packet loss
peer-to-peer energy trading
peer-to-peer energy trading and sharing
social welfare

ASJC Scopus subject areas

Renewable Energy, Sustainability and the Environment
Energy Engineering and Power Technology

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10.35833/MPCE.2020.000136

Cite this

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title = "Multi-commodity Optimization of Peer-to-peer Energy Trading Resources in Smart Grid",

abstract = "Utility maximization is a major priority of prosumers participating in peer-to-peer energy trading and sharing (P2P-ETS). However, as more distributed energy resources integrate into the distribution network, the impact of the communication link becomes significant. We present a multi-commodity formulation that allows the dual-optimization of energy and communication resources in P2P-ETS. On one hand, the proposed algorithm minimizes the cost of energy generation and communication delay. On the other hand, it also maximizes the global utility of prosumers with fair resource allocation. We evaluate the algorithm in a variety of realistic conditions including a time-varying communication network with signal delay signal loss. The results show that the convergence is achieved in a fewer number of time steps than the previously proposed algorithms. It is further observed that the entities with a higher willingness to trade the energy acquire more satisfactions than others.",

keywords = "Distributed algorithm, distributed dual-gradient (DDG), economic dispatch, multi-commodity networks, packet loss, peer-to-peer energy trading, peer-to-peer energy trading and sharing, social welfare",

author = "Olamide Jogunola and Bamidele Adebisi and Kelvin Anoh and Augustine Ikpehai and Mohammad Hammoudeh and Georgina Harris",

note = "Publisher Copyright: {\textcopyright} 2013 State Grid Electric Power Research Institute.",

year = "2022",

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day = "1",

doi = "10.35833/MPCE.2020.000136",

language = "English",

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T1 - Multi-commodity Optimization of Peer-to-peer Energy Trading Resources in Smart Grid

AU - Jogunola, Olamide

AU - Adebisi, Bamidele

AU - Anoh, Kelvin

AU - Ikpehai, Augustine

AU - Hammoudeh, Mohammad

AU - Harris, Georgina

PY - 2022/1/1

Y1 - 2022/1/1

N2 - Utility maximization is a major priority of prosumers participating in peer-to-peer energy trading and sharing (P2P-ETS). However, as more distributed energy resources integrate into the distribution network, the impact of the communication link becomes significant. We present a multi-commodity formulation that allows the dual-optimization of energy and communication resources in P2P-ETS. On one hand, the proposed algorithm minimizes the cost of energy generation and communication delay. On the other hand, it also maximizes the global utility of prosumers with fair resource allocation. We evaluate the algorithm in a variety of realistic conditions including a time-varying communication network with signal delay signal loss. The results show that the convergence is achieved in a fewer number of time steps than the previously proposed algorithms. It is further observed that the entities with a higher willingness to trade the energy acquire more satisfactions than others.

AB - Utility maximization is a major priority of prosumers participating in peer-to-peer energy trading and sharing (P2P-ETS). However, as more distributed energy resources integrate into the distribution network, the impact of the communication link becomes significant. We present a multi-commodity formulation that allows the dual-optimization of energy and communication resources in P2P-ETS. On one hand, the proposed algorithm minimizes the cost of energy generation and communication delay. On the other hand, it also maximizes the global utility of prosumers with fair resource allocation. We evaluate the algorithm in a variety of realistic conditions including a time-varying communication network with signal delay signal loss. The results show that the convergence is achieved in a fewer number of time steps than the previously proposed algorithms. It is further observed that the entities with a higher willingness to trade the energy acquire more satisfactions than others.

KW - Distributed algorithm

KW - distributed dual-gradient (DDG)

KW - economic dispatch

KW - multi-commodity networks

KW - packet loss

KW - peer-to-peer energy trading

KW - peer-to-peer energy trading and sharing

KW - social welfare

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JO - Journal of Modern Power Systems and Clean Energy

JF - Journal of Modern Power Systems and Clean Energy

IS - 1

ER -

Multi-commodity Optimization of Peer-to-peer Energy Trading Resources in Smart Grid

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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Cite this