Relevant bibliographies by topics / Peer-to-peer energy trading

Academic literature on the topic 'Peer-to-peer energy trading'

Author: Grafiati

Published: 10 December 2022

Last updated: 20 February 2023

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Journal articles on the topic "Peer-to-peer energy trading"

Wongthongtham, Pornpit, Daniel Marrable, Bilal Abu-Salih, Xin Liu, and Greg Morrison. "Blockchain-enabled Peer-to-Peer energy trading." Computers & Electrical Engineering 94 (September 2021): 107299. http://dx.doi.org/10.1016/j.compeleceng.2021.107299.

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Tushar, Wayes, Tapan Kumar Saha, Chau Yuen, Thomas Morstyn, Nahid-Al-Masood, H. Vincent Poor, and Richard Bean. "Grid Influenced Peer-to-Peer Energy Trading." IEEE Transactions on Smart Grid 11, no. 2 (March 2020): 1407–18. http://dx.doi.org/10.1109/tsg.2019.2937981.

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R, Sitharthan, Sanjeevikumar Padmanaban, Shanmuga Sundar Dhanabalan, and Rajesh M. "Peer-to-peer energy trading using blockchain technology." Energy Reports 8 (November 2022): 2348–50. http://dx.doi.org/10.1016/j.egyr.2022.01.145.

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Alvaro-Hermana, R., Jesus Fraile-Ardanuy, Pedro J. Zufiria, Luk Knapen, and Davy Janssens. "Peer to Peer Energy Trading with Electric Vehicles." IEEE Intelligent Transportation Systems Magazine 8, no. 3 (2016): 33–44. http://dx.doi.org/10.1109/mits.2016.2573178.

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Ali, Faizan Safdar, Moayad Aloqaily, Omar Alfandi, and Oznur Ozkasap. "Cyberphysical Blockchain-Enabled Peer-to-Peer Energy Trading." Computer 53, no. 9 (September 2020): 56–65. http://dx.doi.org/10.1109/mc.2020.2991453.

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Zhang, Chenghua, Jianzhong Wu, Yue Zhou, Meng Cheng, and Chao Long. "Peer-to-Peer energy trading in a Microgrid." Applied Energy 220 (June 2018): 1–12. http://dx.doi.org/10.1016/j.apenergy.2018.03.010.

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Alam, Muhammad Raisul, Marc St-Hilaire, and Thomas Kunz. "Peer-to-peer energy trading among smart homes." Applied Energy 238 (March 2019): 1434–43. http://dx.doi.org/10.1016/j.apenergy.2019.01.091.

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Khorasany, Mohsen, Yateendra Mishra, and Gerard Ledwich. "Hybrid trading scheme for peer-to-peer energy trading in transactive energy markets." IET Generation, Transmission & Distribution 14, no. 2 (January 31, 2020): 245–53. http://dx.doi.org/10.1049/iet-gtd.2019.1233.

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Wang, Ning, Weisheng Xu, Zhiyu Xu, and Weihui Shao. "Peer-to-Peer Energy Trading among Microgrids with Multidimensional Willingness." Energies 11, no. 12 (November 27, 2018): 3312. http://dx.doi.org/10.3390/en11123312.

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Networked microgrids are emerging for coordinating distributed energy resources in distribution networks in the future Energy Internet, for which developing an efficient energy market model is crucial for facilitating multi-directional trading among microgrids. In this paper, a peer-to-peer energy trading mechanism is presented using non-cooperative bidding among microgrids. Multidimensional willingness, including time pressure and counter behavior for mimicking the personalized behaviors of microgrids, was taken into account in the design of the bidding strategy. Under a parallel trading framework based on a blockchain, the proposed multidimensional willingness bidding strategy turns out to be able to make rational decisions with sufficient flexibility in the bidding process. The simulation results of a realistic case of microgrids from Guizhou Province, China, validate that the proposed peer-to-peer energy trading mechanism is capable of raising the microgrids’ profits and renewable energy source utilization.

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Junlakarn, Siripha, Phimsupha Kokchang, and Kulyos Audomvongseree. "Drivers and Challenges of Peer-to-Peer Energy Trading Development in Thailand." Energies 15, no. 3 (February 8, 2022): 1229. http://dx.doi.org/10.3390/en15031229.

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Recent developments in disruptive technologies along with the cost reduction of photovoltaics have been transforming business models in the electricity sector worldwide. The rise of prosumers has led to a more decentralized and open local green energy market through the emergence of peer-to-peer (P2P) energy trading, where consumers and prosumers can buy or sell electricity through an online trading platform. P2P energy trading has the potential to make green energy more accessible at the local level, provide a customer choice that aligns with community values, and promote the use of renewable energy (RE) for local consumption. Although P2P energy trading has already been adopted in some countries, its implementation remains challenging in other countries, including Thailand. In this work, we investigated the drivers and challenges of implementing P2P energy trading in Thailand based on the perspectives of P2P energy trading pilot project developers participating in the regulatory sandbox program. A strategic framework was used to identify the respondents’ standpoints on the political, economic, social, technological, legal, and environmental (PESTLE) factors that can influence the implementation of P2P energy trading. This can help businesses, policymakers, and regulators better understand drivers and barriers of P2P energy trading, which is a potential local energy market. This paper also provides policy recommendations for regulatory changes for the future development of P2P energy trading, including opening a third-party access (TPA) regime, enabling a liberalized market in the electricity market, and integrating the role and responsibilities of the prosumer for P2P energy trading into existing law.

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Dissertations / Theses on the topic "Peer-to-peer energy trading"

Zhang, Chenghua. "Peer-to-peer energy trading in electrical distribution networks." Thesis, Cardiff University, 2017. http://orca.cf.ac.uk/109074/.

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In response to the challenges posed by the increasing penetration of distributed generation from renewable energy sources and the increasing electricity retail prices with decreasing Feed-In Tariff rates, a new energy trading arrangement, “peer-to-peer (P2P) energy trading” has been proposed. It refers to the direct energy trading among consumers and prosumers in distribution networks, which is developed based on the “P2P economy” concept (also known as sharing economy). A hierarchical system architecture model has been proposed in order to identify and categorise the key elements and technologies involved in P2P energy trading. A P2P energy trading platform called “Elecbay” is designed. The P2P bidding is simulated using game theory. Test results in a grid-connected LV Microgrid with distributed generators and flexible demands show that P2P energy trading is able to improve the local balance of energy generation and consumption, and the enhanced variety of peers is able to further facilitate the balance. Two necessary control systems are proposed for the Microgrid with “Elecbay”. A voltage control system which combines droop control and on-load-tap-changer (OLTC) control is designed and simulated. Simulation results show that the proposed voltage control system is sufficient for supporting the P2P energy trading in the Microgrid. The total number of operation times of the OLTC is reduced with P2P energy trading compared to the reference scenario. The information and communication technology (ICT) infrastructures for the P2P bidding platform and the voltage control system are investigated. The information exchange among peers and other parties (Elecbay, distribution system operators, etc.) is designed based on TCP/IP protocol. Existing and private communication networks with different communication medium, bandwidths, etc., are modelled. Simulation results show that the existing ICT infrastructures are sufficient for supporting both the P2P energy trading platform and the voltage control system. Therefore, no large amount of additional investments are required.

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Khorasany, Mohsen. "Market design for peer-to-peer energy trading in a distribution network with high penetration of distributed energy resources." Thesis, Queensland University of Technology, 2020. https://eprints.qut.edu.au/135559/1/Mohsen_Khorasany_Thesis.pdf.

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This thesis examines different market structures for peer-to-peer (P2P) energy trading. Different market clearing mechanisms are designed for market settlement, including auction-based method, distributed optimisation, and decentralised market clearing. Also, price signals are introduced to model network constraints in any individual transaction in the electricity market. Moreover, a segmentation method is proposed to enhance the scalability of the P2P markets, using the clustering method.

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Guerrero, Orbe Jaysson Esteban. "Transactive Energy in Low-Voltage Networks." Thesis, University of Sydney, 2020. https://hdl.handle.net/2123/23226.

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Over recent years, distributed energy resources (DER) have been the object of many studies, which recognise and establish their emerging role in the future of power systems. Given this context, the concept of transactive energy (TE) has emerged as a central element to the vision of the future grid. The transition to the emerging TE concept requires to tap the inherent flexibility of the demand-side. In this context, the concept of peer-to-peer (P2P) energy trading between consumers and prosumers is one of the new scenarios of growing importance in the domain of distribution networks. This local energy market has been proposed as a means of efficiently managing the uptake of DER. However, the deployment of P2P energy markets at the distribution level is not clear yet. Few studies have investigated the implementation of local energy markets in distribution systems. It is necessary to examine in more detail the limitations and rules that will allow and support the electrical energy trading in a local energy market. Network constraints must be considered in order to evaluate the impact in the network and satisfy the constraints of the grid. In addition, the real benefits for end-users are not yet known. Likewise, it is not known whether this would favour power systems or not. Furthermore, market structures and agents’ strategies need also to be studied. Those factors influence the performance and efficiency of the market. Hence, there are some fundamental questions that have to be solved first in order to implement local markets. This research aims to contribute to this growing area by exploring the operation and implementation of P2P markets on distribution networks using new methodologies and tools. This study also provides a systematic analysis of other prominent DER integration approaches that have been proposed in the transition towards a transactive energy system.

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Sivaramakrishnan, Vignesh. "Peer to peer energy and water trading in the Wheatbelt: A sustainable move towards achieving energy and water independence for farm communities." Thesis, Sivaramakrishnan, Vignesh (2020) Peer to peer energy and water trading in the Wheatbelt: A sustainable move towards achieving energy and water independence for farm communities. Masters by Coursework thesis, Murdoch University, 2020. https://researchrepository.murdoch.edu.au/id/eprint/61269/.

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Energy and water systems in the West Australian Wheatbelt require optimization, as they are being delivered through a centralized infrastructure that is unsustainable in the long run and would be prone to impacts from climate change. Furthermore, there are vast complexities in integrating sustainable energy sources currently and their systems due to inherent hardships present in the remote control and management of such energy forms. This project aims to integrate distributed energy resources (DERs) for the desired application using the key elements mentioned above. Blockchain technology facilitates peer-to-peer (P2P) transmission and trading while having a robust consensus and encryption along with the employability of smart contracts that help non-trusting entities to trade energy using a decentralized platform, using this, a methodology is presented that provides for a pathway towards implementation. It is also shown how P2P energy trading acts as a driver to instate P2P water trading, by drawing parallels between water and energy supply systems in terms of infrastructural needs. The three main parts that energy microgrids are comprised of are generation, storage, and distribution. These can be directly correlated to a function that would be required of water trading networks. The faltering GAWS (Goldfields Agricultural Water Supply Scheme) is well known and the thesis aims to provide path to install P2P energy and water trading by consolidating resources from existing projects and through analysing literature from the identified key elements around which the project is based; blockchain technology, PV installations and solar pumps with RO, policy instruments that would control the outcome of the project and, energy and water trading. Since an official consensus was not available w.r.t the validity of the GAWS infrastructure in Muresk, GeoVIEW was used to pursue modelling, where in, the man-made water channels have been wilfully interpreted as water distribution networks. Three scenarios are simulated (single farm + single PVRO; several farms + single PVRO; small town & farms + 4 x PVRO) to show the working in different setup architectures and the most optimal one for the proposed usage is identified. A method to elucidate the setup of smart contracts is also shown. It incorporates the elements together, and equations are formed to design and scale the project for different applications. The objectives of the thesis are assessed along with the challenges that would be faced that are inherent in applying such concepts. It is empirically shown that this project can significantly outperform legacy networks and help in achieving water and energy independence for the Wheatbelt in the long run. Recommendations are formulated to create the best environment that would be conducive to its application.

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Chousal, Miguel Rodrigues Castro. "Renewable Energy Trading Using Peer-to-Peer Business Models." Master's thesis, 2020. https://hdl.handle.net/10216/132794.

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The appearance of more proactive consumers, the commonly termed prosumers, is empowering the consumers and bringing new opportunities and challenges to the operation of power systems in a market environment. Recently, the so-called peer-to-peer (P2P) electricity markets conceptually allows the aforementioned prosumers to directly share their electricity contributing to more rapidly recover investment costs. Such P2P markets give the opportunity to consumers to freely choose who to buy electricity from. A community can also be created by prosumers who want to collaborate with each other. According to these ideas, this project focus on proving the concept of these new P2P markets (full P2P, Community P2P, Hybrid P2P). In order to achieve this goal, initially, a test grid is created and analysed without any P2P transactions. Subsequently, the mentioned P2P models are individually evaluated on Python 3 with Gurobi Optimizer, in order to determine which of them is the most advantageous.
O aparecimento de consumidores mais proativos, vulgarmente designados por prosumers, está a capacitar os consumidores e a trazer novas oportunidades e desafios para a operação de sistemas de energia no âmbito do desenvolvimento dos mercados de electricidade. Recentemente, o conceito peer-to-peer (P2P) permite aos prosumers acima referidos partilhar diretamente a sua energia eléctrica e de assim justificarem e recuperarem mais rapidamente custos de investimento. Esses mercados P2P dão aos consumidores a oportunidade de escolher livremente a quem comprar energia elétrica. Uma comunidade também pode ser criada por prosumers que queiram colaborar uns com os outros. Este projeto pretende comprovar o conceito destes novos mercados P2P (full P2P, community P2P e Hybrid P2P). Inicialmente, foi criada e analisada uma rede teste sem qualquer modelo P2P. Posteriormente, os modelos P2P mencionados são avaliados individualmente em Python 3 e utilizando o otimizador Gurobi, a fim de determinar qual deles é o mais vantajoso.

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Chousal, Miguel Rodrigues Castro. "Renewable Energy Trading Using Peer-to-Peer Business Models." Dissertação, 2020. https://hdl.handle.net/10216/132794.

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"Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks." Master's thesis, 2019. http://hdl.handle.net/2286/R.I.55571.

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abstract: Blockchain technology enables peer-to-peer transactions through the elimination of the need for a centralized entity governing consensus. Rather than having a centralized database, the data is distributed across multiple computers which enables crash fault tolerance as well as makes the system difficult to tamper with due to a distributed consensus algorithm. In this research, the potential of blockchain technology to manage energy transactions is examined. The energy production landscape is being reshaped by distributed energy resources (DERs): photo-voltaic panels, electric vehicles, smart appliances, and battery storage. Distributed energy sources such as microgrids, household solar installations, community solar installations, and plug-in hybrid vehicles enable energy consumers to act as providers of energy themselves, hence acting as 'prosumers' of energy. Blockchain Technology facilitates managing the transactions between involved prosumers using 'Smart Contracts' by tokenizing energy into assets. Better utilization of grid assets lowers costs and also presents the opportunity to buy energy at a reasonable price while staying connected with the utility company. This technology acts as a backbone for 2 models applicable to transactional energy marketplace viz. 'Real-Time Energy Marketplace' and 'Energy Futures'. In the first model, the prosumers are given a choice to bid for a price for energy within a stipulated period of time, while the Utility Company acts as an operating entity. In the second model, the marketplace is more liberal, where the utility company is not involved as an operator. The Utility company facilitates infrastructure and manages accounts for all users, but does not endorse or govern transactions related to energy bidding. These smart contracts are not time bounded and can be suspended by the utility during periods of network instability.
Dissertation/Thesis
Masters Thesis Computer Science 2019

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Klein, Lurian Pires. "Revealing social values in the context of peer-to-peer energy sharing: a methodological approach." Doctoral thesis, 2021. http://hdl.handle.net/10316/98614.

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Tese de Doutoramento em Sistemas Sustentáveis de Energia apresentada à à Faculdade de Ciências e Tecnologia da Universidade de Coimbra.
The peer-to-peer energy sharing concept refers to flexible, decentralised, synergistic, and direct exchanges of (often the case) distributed renewable electricity between grid-connected end-users. Fundamentally, peer-to-peer energy sharing models are based on complex social networks that thrive on the local embeddedness and social wiring among end-users, rather than on competing economic self-interests. This challenges the traditional approach of energy markets, which is usually characterised by a rigid top-down hierarchical structure that leads to individualistic and antagonistic behaviours at the end-user level. By evidencing the intricate social interconnectedness that characterises peer-to-peer energy sharing models, this Ph.D. research argues that these models might influence the social values systems of those directly involved with it. Nonetheless, the scientific literature still fails to provide fit-for-purpose methodologies that can transfer the inherently qualitative nature of social values into quantitative measures in the context of peer-to-peer energy sharing. In view of that, this Ph.D. research aims to provide the first systematic investigation of the social values-based dimension of peer-to-peer energy sharing models. To do so, it developed the first overarching social values-based assessment framework that allows the identification of underlying social values associated with peer-to-peer energy sharing model. This framework was trialled and validated in three pilots in Portugal from the Community S demonstration project - the first to have validated the concept of peer-to-peer energy sharing in real-life settings and under real market conditions before its deregulation in the country. Because of that, this Ph.D. research also demonstrated and validated the business model behind the Community S project, as well as the end-user engagement framework that guaranteed its sucessful roll out. The impact of the social values-based assessment framework was analysed. A valuable element of this framework is the overarching reference list of 194 individual social values that can be explicitly associated with peer-to-peer energy sharing interactions, which were categorised under 33 social value macro themes for operationalisation purposes. Results suggest that 26 out of the 33 social value macro themes were considered validly “active” in the context of the pilot sites, including: belonging, achievement, responsibility, resilience, altruism, influence, emancipation, awareness, participation, collaboration, collectivity, dialogue, support, commitment, motivation, impartiality, progress, professionalism, environmentalism, purpose, originality, personal development, wellbeing, effect change, advocacy, and long-sightedness. The social values-based framework also allowed participants to make inferences about the nature of each active social value uncovered. In this respect, participants perceived these 26 active social value macro themes as previously existing social values that were reinforced by the peer-to-peer energy sharing activities. Participants also identified coercion as a social value macro theme that did not relate to peer-to-peer energy sharing. These results are scalable provided that the result interpretations drawn here are put in perspective and validated through the cohesive validity check on a case-by-case basis proposed by this Ph.D. research. All is all, This Ph.D. research defends that there must be a fundamental shift in the way that social values are accounted for in the transition towards a desirable carbon-neutral future. Since only part of the overall value created by peer-to-peer energy sharing models seems to be assimilated into market relations, this Ph.D. research highlighted the need to demonstrate the real impact of what can be truly achieved with peer-to-peer energy sharing, instead of just what is easily quantifiable. For that, social values should be considered core outcomes of peer-to-peer energy sharing services provision and commissioning, rather than just an incremental externality. In conclusion, this Ph.D. research expects to create a new social values-based language that is explicitly associated with peer-to-peer energy sharing.
O conceito de partilha de energia entre pares refere-se às transações diretas, descentralizadas, sinérgicas e flexíveis do excedente de produção fotovoltaica entre utilizadores finais conectados entre si pela rede de energia. Fundamentalmente, os modelos de partilha de energia entre pares são baseados em redes sociais complexas que prosperam na integração local e na interconexão social entre os utilizadores finais, em vez de interesses econômicos individualizados e concorrentes. Isso desafia a abordagem tradicional dos mercados de energia, que geralmente é caracterizada por uma estrutura hierárquica rígida de cima para baixo que leva a comportamentos individualistas e antagônicos ao nível do utilizador final. Ao evidenciar a intrincada interconexão social que caracteriza os modelos de partilha de energia entre pares, esta tese de doutoramento argumenta que tais modelos podem vir a exercer certa influência nos sistemas de valores sociais das pessoas diretamente envolvidas com eles. No entanto, a literatura científica ainda não oferece metodologias capazes de avaliar objetivamente a natureza inerentemente qualitativa dos valores sociais no contexto da partilha de energia entre pares. Em vista disso, esta tese de doutoramento visa fornecer a primeira investigação sistemática da dimensão dos valores sociais associada aos modelos de partilha de energia entre pares. Para isso, esta tese de doutoramento desenvolveu o primeiro quadro metodológico abrangente capaz de identificar valores sociais subjacentes associados à partilha de energia entre pares. Este quadro metodológico foi testado e validado em três pilotos em Portugal sob a tutela do projeto demonstrador Community S - o primeiro a ter validado o conceito de partilha de energia entre pares em cenários reais e em condições reais de mercado antes da sua desregulamentação no país. Por causa disso, esta tese de doutoramento também demonstrou e validou o modelo de negócios por trás do projeto Community S, bem como o quadro metodológico de envolvimento dos participantes desenvolvido sob medida para garantir a sua implementação bem-sucedida. O impacto do quadro metodológico de avaliação dos valores sociais foi analisado. Um elemento valioso deste quadro metodológico é a lista de referência de valores sociais que abrange 194 valores sociais individuais distintos e explicitamente associados à partilha de energia entre pares - categorizados em 33 macro valores sociais (ou seja, macro temas) para fins de operacionalização dos valores sociais. Os resultados sugerem que 26 dos 33 macro temas foram considerados validamente "ativos" no contexto dos três pilotos, incluindo: sentimento de pertença, realização, responsabilidade, resiliência, altruísmo, influência, emancipação, consciêncialização, participação, colaboração, identidade comunitária, diálogo, suporte, comprometimento, motivação, imparcialidade, progresso, profissionalismo, consciência ambiental, propósito, originalidade, desenvolvimento pessoal, bem-estar, impacto, defesa (de uma causa) e visão de longo prazo. O quadro metodológico proposto também permitiu aos participantes fazer inferências sobre a natureza de cada macro tema ativo revelado. A este respeito, os participantes concluiram que os 26 macro temas ativos representam valores sociais previamente existentes que foram reforçados pela partilha de energia entre pares. Os participantes também identificaram coerção como um macro tema não relacionado à partilha de energia entre pares. Esses resultados são escaláveis, desde que as interpretações dos resultados aqui traçadas sejam colocadas em perspectiva e validadas caso-a-caso por meio do quadro de validação coeso proposto nesta tesa de doutoramento. Em suma, esta tese de doutoramento defende que deve haver uma mudança estrutural na forma como os valores sociais são valorizados na atual transição energética rumo à descarbonização. Uma vez que apenas parte do valor geral criado pelos modelos de partilha de energia entre pares parece ser assimilado pelas relações de mercado, esta tese de doutoramento reforça a necessidade de demonstrar o impacto real alcançado pelos modelos de partilha de energia entre pares, em vez de apenas o que pode ser quantificável. Para isso, os valores sociais devem ser considerados como aspectos centrais do fornecimento e comissionamento de serviços de partilha de energia entre pares, ao invés de apenas uma externalidade incremental. Por fim, esta tese de doutoramento espera ter criado uma nova linguagem centrada em valores sociais que está explicitamente associada à partilha de energia entre pares.
The Nippon Foundation and the Tokyo Foundation for Policy Research (Sylff Fellowship in 2017, Sylff Research Abroad in 2019, Sylff COVID-19 Relief)

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Book chapters on the topic "Peer-to-peer energy trading"

Morstyn, Thomas, and Malcolm D. McCulloch. "Peer-to-Peer Energy Trading." In Analytics for the Sharing Economy: Mathematics, Engineering and Business Perspectives, 279–300. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-35032-1_16.

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Gray, Gerald R. "Peer-to-Peer Energy Trading and Transactive Energy." In Blockchain Technology for Managers, 135–41. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-85716-5_14.

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Lee, Joseph. "The Peer-to-Peer Energy Trading Platform." In Crypto-Finance, Law and Regulation, 188–209. London: Routledge, 2021. http://dx.doi.org/10.4324/9780429023613-10.

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Vishwakarma, Amit Kumar, Haiwang Zhong, and Yatindra Nath Singh. "Consensus Mechanism for Peer-to-Peer Energy Trading." In Lecture Notes in Electrical Engineering, 355–64. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-2761-3_33.

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Sivianes, Manuel, and Carlos Bordons. "Application of Blockchain to Peer to Peer Energy Trading in Microgrids." In Blockchain and Applications, 138–48. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-86162-9_14.

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Li, Songnong, Lefeng Shi, and Song Wang. "A Mix Peer-To-Peer Energy Trading Hierarchy Modal for Prosumers." In Lecture Notes in Electrical Engineering, 1020–28. Singapore: Springer Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-1528-4_104.

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Scuri, Sabrina, Gergana Tasheva, Luísa Barros, and Nuno Jardim Nunes. "An HCI Perspective on Distributed Ledger Technologies for Peer-to-Peer Energy Trading." In Human-Computer Interaction – INTERACT 2019, 91–111. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-29387-1_6.

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Eon, Christine, Xin Liu, and Gregory M. Morrison. "Potential for Peer-to-Peer Trading of Energy Based on the Home System of Practice." In Sustainability in Energy and Buildings 2018, 478–86. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-030-04293-6_46.

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Das, Ritweek, Stuti Snata Ray, Gayatri Mohapatra, and Sanjeeb Kumar Kar. "A Review of Challenges and Solution in Peer-to-Peer Energy Trading of Renewable Sources." In Biologically Inspired Techniques in Many Criteria Decision Making, 307–14. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-16-8739-6_28.

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Shukla, Saurabh, Subhasis Thakur, Shahid Hussain, and John G. Breslin. "A Blockchain-Enabled Fog Computing Model for Peer-To-Peer Energy Trading in Smart Grid." In Blockchain and Applications, 14–23. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-86162-9_2.

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Conference papers on the topic "Peer-to-peer energy trading"

Yao, Haotian, Yue Xiang, Junyong Liu, and Shuai Hu. "Multi-area Peer-to-Peer Energy Trading." In 2020 IEEE Student Conference on Electric Machines and Systems (SCEMS). IEEE, 2020. http://dx.doi.org/10.1109/scems48876.2020.9352416.

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Martinez-Trejo, Diana. "Blockchain-based Peer-to-Peer Energy Trading." In 2020 IEEE PES Transactive Energy Systems Conference (TESC). IEEE, 2020. http://dx.doi.org/10.1109/tesc50295.2020.9656943.

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Denysiuk, Roman, Fabio Lilliu, Diego Recupero, and Meritxell Vinyals. "Peer-to-peer Energy Trading for Smart Energy Communities." In 12th International Conference on Agents and Artificial Intelligence. SCITEPRESS - Science and Technology Publications, 2020. http://dx.doi.org/10.5220/0008915400400049.

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Noori, Amir, Babak Tavassoli, and Alireza Fereidunian. "Incentivizing Peer-to-Peer Energy Trading in Microgrids." In 2021 29th Iranian Conference on Electrical Engineering (ICEE). IEEE, 2021. http://dx.doi.org/10.1109/icee52715.2021.9544467.

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Budak, Caner, Ulas Erdogan, and Sinan Kufeoglu. "Smart Contract Development for Peer-to-Peer Energy Trading." In 2022 IEEE 7th International Energy Conference (ENERGYCON). IEEE, 2022. http://dx.doi.org/10.1109/energycon53164.2022.9830493.

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Feng, Yingchun, Jie Fan, Jiale Wang, and Yachao Li. "Peer-to-peer Energy Trading Platform Using Consortium Blockchain." In 2020 12th IEEE PES Asia-Pacific Power and Energy Engineering Conference (APPEEC). IEEE, 2020. http://dx.doi.org/10.1109/appeec48164.2020.9220403.

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Iskakova, Aigerim, H. S. V. S. Kumar Nunna, and Pierluigi Siano. "Ethereum Blockchain-Based Peer-To-Peer Energy Trading Platform." In 2020 IEEE International Conference on Power and Energy (PECon). IEEE, 2020. http://dx.doi.org/10.1109/pecon48942.2020.9314591.

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Jogunola, Olamide, Mohammad Hammoudeh, Kelvin Anoh, and Bamidele Adebisi. "Distributed Ledger Technologies for Peer-to-Peer Energy Trading." In 2020 IEEE Electric Power and Energy Conference (EPEC). IEEE, 2020. http://dx.doi.org/10.1109/epec48502.2020.9320061.

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Long, Chao, Jianzhong Wu, Chenghua Zhang, Lee Thomas, Meng Cheng, and Nick Jenkins. "Peer-to-peer energy trading in a community microgrid." In 2017 IEEE Power & Energy Society General Meeting (PESGM). IEEE, 2017. http://dx.doi.org/10.1109/pesgm.2017.8274546.

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Reports on the topic "Peer-to-peer energy trading"

de Almeida, Lucila. Peer-to-Peer Trading and Energy Community in the Electricity Market : Analysing the Literature on Law and Regulation and Looking Ahead to Future Challenges. User-Centred Energy Systems Technology Collaboration Programme, April 2021. http://dx.doi.org/10.47568/5xr108.

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Academic literature on the topic 'Peer-to-peer energy trading'

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Contents

Journal articles on the topic "Peer-to-peer energy trading"

Dissertations / Theses on the topic "Peer-to-peer energy trading"

Book chapters on the topic "Peer-to-peer energy trading"

Conference papers on the topic "Peer-to-peer energy trading"

Reports on the topic "Peer-to-peer energy trading"