Construction of the Multi-Agent Environment Architecture of the Pricing Process Simulation Model in the Electricity Market-Reference-Cited by-同舟云学术

Construction of the Multi-Agent Environment Architecture of the Pricing Process Simulation Model in the Electricity Market

Published:2023-12-10 Issue:6 Volume:45 Page:15-30
ISSN:0204-3572
Container-title:Èlektronnoe modelirovanie
language:
Short-container-title:Èlektron. model.

Author:

Borukaiev Z.Kh.,Evdokimov V.A.,Ostapchenko K.B.

Abstract

The question of building the architecture of the multi-agent environment of the simulation model of the pricing process, as a space of heterogeneous interconnected organizational, infor-mational, technological and economic interactions of the simulated agents of the pricing pro-cess, is considered.Using the example of a complex organizational and technical system (COTS) of the electricity micro-market in local electric power systems, the set of agents sur-rounding them and ensuring the vital activity of the COTS of pricing is formalized, consisting of classified internal agents and environmental agents with a definition of their functional pur-pose. It was established that a set of partially observable influence factors of subjects of the electricity micro-market external environment are additionally formalized in the multi-agent pricing system as communication agents with stochastic, dynamic. but with discrete fixation of distinct states of observation processes in this environment. As a result, the simulation model of the pricing process is presented as a heterogeneous distributed multi-agent system.

Publisher

National Academy of Sciences of Ukraine (Co. LTD Ukrinformnauka) (Publications)

Reference21 articles.

1. Mokhor, V.V. and Evdokimov, V.A. (2020), "Creation of a multi-agent simulation model of pricing processes in the electricity market", Elektronne Modelyuvannya, Vol. 42, no. 6, pp. 3-17, available at: https://doi.org/10.15407/emodel.42.06.

2. Kyrylenko, A.V. ed. (2016), Intelligent electric power systems: elements and modes, Institut elektrodinamiki, Kyiv, Ukraine, available at: https://www.ied.org.ua/files/book3.pdf.

3. Denisyuk, S.P., Bazyuk, T.M., Fedosenko, M.M. and Yarmolyuk, O.S. (2017), Power supply systems with an active consumer: models and modes, AVERS, Kyiv, Ukraine. 182

4. Kyrylenko, O.V., Denysyuk, S.P., Tankevich, S.E. and Bazyuk, T.M. (2016), "Information and regulatory support for the organization of multi-agent management of the electric power system with an active consumer", Information technology and computer engineering, no. 1, pp. 29-34.

5. Saukh, S.E. and Borysenko, A.V. (2023), "Mathematical model of a flexible micro grid integrated into the country grid", Tekhnichna Elektrodynamika, no. 2, pp. 61-68, available at: https://doi.org/10.15407/techned2023.02.061.