Nongmaithem Nandini Devi; Surmila Thokchom;Nongmaithem Nandini Devi
Harvested from ORCID Public Data FileNongmaithem Nandini Devi in OpenAIRE
Thoudam Doren Singh; Gayadhar Panda; +1 AuthorsThoudam Doren Singh
Derived by OpenAIRE algorithms or harvested from 3rd party repositoriesThoudam Doren Singh in OpenAIRE Nongmaithem Nandini Devi; Surmila Thokchom;Nongmaithem Nandini Devi
Harvested from ORCID Public Data FileNongmaithem Nandini Devi in OpenAIRE Thoudam Doren Singh; Gayadhar Panda;Thoudam Doren Singh
Derived by OpenAIRE algorithms or harvested from 3rd party repositoriesThoudam Doren Singh in OpenAIRE Ramasamy Thaiyal Naayagi; Ramasamy Thaiyal Naayagi
Harvested from ORCID Public Data FileRamasamy Thaiyal Naayagi in OpenAIREDue to global warming and climate change, it is essential to produce power using renewable sources, such as solar, wind, fuel cells, etc. The traditional grid shifts towards the smart grid by infusing digital communication techniques and information technology. As the current power system is shifting towards a smart grid, the utility and prosumers participate in the energy trading process. Due to the distributed nature of the smart grid, providing a fair price among them is becoming a difficult task. The article introduces a model for energy trading in a smart grid by allowing participants to negotiate in multiple stages using a game-theory-based multi-stage Nash Bargaining Solution (NBS). The model’s application of game theory enables the participants to decide on a mutually acceptable price, thereby encouraging the utility, private parties and prosumers (those who are able to generate and consume energy) to participate in the trading process. Since all parties participate in the trading procedure, greenhouse gas emissions are reduced. The proposed model also balances the benefits of consumers and producers in the final agreed fixed price. To demonstrate the efficacy of the proposed work, we compare the analytical results with feed-in-tariff (FiT) techniques in terms of consumers’ energy bills and producers’ revenue. For experimental analysis, 20 participants are considered, where the percentage reduction in the bill of each consumer and the percentage increment of revenue of each producer are compared to FiT. On average, the overall bill of the consumer is reduced by 32.8%, and the producers’ revenue is increased by 64.83% compared to FiT. It has been shown further that the proposed model shows better performance as compared to FiT with an increase in the number of participants. The analysis of carbon emission reduction in the proposed model has been analyzed, where, for 10 participants, the carbon emission reduction is approximately 28.48 kg/kWh, and for 100 participants is 342.397 kg/kWh.
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