Transactive energy trading in distribution systems via privacy-preserving distributed coordination.

This paper presents an approach to the transactive energy (TE) market that aims to improve the network efficiency and fairness of electricity market in distribution systems. The TE market is designed to allow subscribers to trade electricity in real-time based-on their energy consumption and generation forecast. The proposed framework utilizes distribution locational marginal pricing (DLMP), which accurately reflects the costs of electricity transmission and distribution, to fairly allocate these costs among subscribers. The Small Neighborhood Search Optimal Points (SNSOP) algorithm is then introduced to solve the challenge of finding optimal points for all participants in the TE market, as the maximum financial gain for one participant comes at the maximum financial loss of another participant. The results of the case study show that the proposed framework leads to a more efficient and reliable electricity network, by enabling decentralized control and reducing losses through optimal trades in the TE market. • A decentralized transactive energy framework is proposed for peer-to-peer electricity market. • Distribution locational marginal pricing values energy based-on network constraints. • A distributed algorithm coordinates participants while preserving privacy of sensitive data. • Case studies demonstrate network efficiency improvement by transactions. • Integrated techno-economic modeling ensures physical feasibility energy transfers. [ABSTRACT FROM AUTHOR]