Smart City Gnosys
Smart city article details
| Title | Peer-To-Peer Energy Trading Case Study Using An Ai-Powered Community Energy Management System |
|---|---|
| ID_Doc | 41553 |
| Authors | Mahmoud M.; Slama S.B. |
| Year | 2023 |
| Published | Applied Sciences (Switzerland), 13, 13 |
| DOI | http://dx.doi.org/10.3390/app13137838 |
| Abstract | The Internet of Energy (IoE) is a topic that industry and academics find intriguing and promising, since it can aid in developing technology for smart cities. This study suggests an innovative energy system with peer-to-peer trading and more sophisticated residential energy storage system management. It proposes a smart residential community strategy that includes household customers and nearby energy storage installations. Without constructing new energy-producing facilities, users can consume affordable renewable energy by exchanging energy with the community energy pool. The community energy pool can purchase any excess energy from consumers and renewable energy sources and sell it for a price higher than the feed-in tariff but lower than the going rate. The energy pricing of the power pool is based on a real-time link between supply and demand to stimulate local energy trade. Under this pricing structure, the cost of electricity may vary depending on the retail price, the number of consumers, and the amount of renewable energy. This maximizes the advantages for customers and the utilization of renewable energy. A Markov decision process (MDP) depicts the recommended power to maximize consumer advantages, increase renewable energy utilization, and provide the optimum option for the energy trading process. The reinforcement learning technique determined the best option in the renewable energy MDP and the energy exchange process. The fuzzy inference system, which takes into account infinite opportunities for the energy exchange process, enables Q-learning to be used in continuous state space problems (fuzzy Q-learning). The analysis of the suggested demand-side management system is successful. The efficacy of the advanced demand-side management system is assessed quantitatively by comparing the cost of power before and after the deployment of the proposed energy management system. © 2023 by the authors. |
| Author Keywords | artificial intelligence; deep reinforcement learning; peer-to-peer energy trading; prosumer; renewable energy |
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