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Article information
2022 , Volume 27, ¹ 5, p.30-42
Bychkov I.V., Feoktistov A.G., Kostromin R.O., Basharina O.Y., Sidorov I.A.
Simulation of operating environmentally friendly equipment of infrastructure objects in microservice environment
Nowadays, operation of infrastructure objects has a significant impact on the ecology of natural territories. Modelling object operation that takes into account meteorological conditions allows evaluating the degree of observable negative impact that affects the object functioning and making decision to mitigate possible consequences. In the paper, we propose a new approach for simulation modelling the operation for environmentally friendly equipment of infrastructure objects located in the Baikal natural territory. Within the proposed approach, we have developed tools based on microservice architecture. These tools are intended to prepare and carry out large-scale experiments in a heterogeneous distributed computing environment using GPSS models for simulating the equipment operation. In particular, the tools support high-performance computing, hybrid modelling using multi-agent technologies and multi-cloud computing, and mechanisms for multi-criteria decisi- on-making based on simulation results. All procedures with respect to data preparing, executing models, and analyzing the simulation results are implemented by as microservices. Using these tools, we have created web services for evaluating the economic efficiency of environmentally friendly heat supply technology for a typical tourist recreation center using heat pumps under various operating conditions. The advantages of the proposed tools in comparison with the tools of similar purpose are indicated. The developed tools can be used to study the functioning of other similar objects, such as children’s camps, museums, exhibition centers, etc
[full text] [link to elibrary.ru]
Keywords: infrastructure objects, environmentally friendly equipment, monitoring, modelling, microservices
doi: 10.25743/ICT.2022.27.5.004
Author(s):
Bychkov Igor Vyacheslavovich
Dr. , Academician RAS, Professor
Position: Director
Office: Institute for System Dynamics and Control Theory of Siberian Branch of Russian Academy of Sciences
Address: 664033, Russia, Irkutsk, Lermontova st., 134
Phone Office: (3952) 45-30-61
E-mail: idstu@icc.ru
SPIN-code: 5816-7451Feoktistov Alexander Gennadievich
Dr. , Associate Professor
Position: Leading research officer
Office: Institution of the Russian Academy of Sciences Institute for System Dynamics and Control Theory of SB RAS
Address: 664033, Russia, Irkutsk, Lermontova st., 134
Phone Office: (3952) 45-31-54
E-mail: agf@icc.ru
SPIN-code: 5743-1777Kostromin Roman Olegovich
PhD. , Associate Professor
Position: Research Scientist
Office: Institution of the Russian Academy of Sciences Institute for System Dynamics and Control Theory of SB RAS
Address: 664033, Russia, Irkutsk, Lermontova st., 134
Phone Office: (3952) 45-30-62
E-mail: roman@kostromin.net
SPIN-code: 9138-4673Basharina Olga Yurievna
PhD. , Associate Professor
Position: Research Scientist
Office: Institution of the Russian Academy of Sciences Institute for System Dynamics and Control Theory of SB RAS
Address: 664033, Russia, Irkutsk, Lermontova st., 134
Phone Office: (3952) 45-30-62
E-mail: basharinaolga@mail.ru
Sidorov Ivan Alexandrovich
PhD.
Position: Research Scientist
Office: Institution of the Russian Academy of Sciences Institute for System Dynamics and Control Theory of SB RAS
Address: 664033, Russia, Irkutsk, Lermontova st., 134
Phone Office: (3952) 45-31-54
E-mail: ivan.sidorov@icc.ru
References:
[1] Qi Q., Zhao D., Liao T.W., Tao F. Modeling of cyber-physical systems and digital twin based on edge computing, fog computing and cloud computing towards smart manufacturing. Proceedings of the 13th International Manufacturing Science and Engineering Conference (MSEC), College Station. Texas; 2018: 51–85, DOI:10.1115/MSEC2018-6435.
[2] Fuller A., Fan Z., Day C., Barlow C. Digital twin: Enabling technologies, challenges and open research. IEEE Access. 2020; (8):108952–108971. DOI:10.1109/ACCESS.2020.2998358. Available at: https://ieeexplore.ieee.org/document/9103025.
[3] Law A. How to conduct a successful simulation study. Proceedings of the 2003 IEEE Winter Simulation Conference (WSC). New Orleans; 2003: 66–70. DOI:10.1109/WSC.2003.1261409.
[4] Fan Ì., Zhang Z., Wang C. Mathematical models and algorithms for power system optimization: modeling technology for practical engineering problems. London: Academic Press; 2019: 429.
[5] Tako A.A., Robinson S. The application of discrete event simulation and system dynamics in the logistics and supply chain context. Decision Support System. 2012; 52(4):802–815. DOI:10.1016/j.dss.2011.11.015. Available at: https://www.sciencedirect.com/science/article/abs/pii/S0167923611002211.
[6] Tao F., Cheng J., Qi Q., Zhang M., Zhang H., Sui F. Digital twin-driven product design, manufacturing and service with Big Data. The International Journal of Advanced Manufacturing Technology. 2018; (94):3563–3576. DOI:10.1007/s00170-017-0233-1. Available at: https://link.springer.com/article/10.1007/s00170-017-0233-1.
[7] Latysheva I., Vologzhina S., Barkhatova O., Loshchenko C., Sutyrina E. Circulation factors in climate change in the Baikal region. Proceedings of the 25th International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics. Novosibirsk; 2019: 112086L. DOI:10.1117/12.2538282.
[8] Fortino G., Gravina R., Russo W., Savaglio C. Modeling and simulating Internet-of-Things systems: a hybrid agent-oriented approach. Computing in Science & Engineering. 2017; 19(5):68–76. DOI:10.1109/MCSE.2017.3421541. Available at: https://ieeexplore.ieee.org/document/8024135.
[9] Schriber T.J. Simulation using GPSS. New York: John Wiley & Sons; 1974: 533.
[10] AnyLogic: simulation modelling for business. The AnyLogic Company; 2022. Available at: https://www.anylogic.ru. (accessed at May 29, 2022) (In Russ.)
[11] Paul P.K., Aithal P.S., Bhuimali A., Tiwary K.S., Saavedra R., Aremu B. Geo information systems and remote sensing: applications in environmental systems and management. International Journal of Management, Technology, and Social Sciences. 2020; 5(2):11–18. Available at: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3724127.
[12] Devyatkov V.V., Devyatkov T.V., Fedotov M.V. Imitatsionnye issledovaniya v srede modelirovaniya GPSS Studio [Simulation studies in the GPSS STUDIO simulation environment]. Moscow: Vuzovskiy Uchebnik, INFRA-M; 2019: 283. (In Russ.)
[13] Moore R.V., Tindall C.I. An overview of the open modelling interface and environment (the OpenMI). Environmental Science & Policy. 2005; 8(3):279–286. DOI:10.1016/j.envsci.2005.03.009. Available at: https://www.sciencedirect.com/science/article/abs/pii/S1462901105000456.
[14] Bychkov I., Feoktistov A., Kostromin R., Sidorov I., Edelev A., Gorsky S. Machine learning in a multi-agent system for distributed computing management. Proceedings of the International Conference “Information Technology and Nanotechnology. Session Data Science”. Samara; 2018; (2212):89–97. Available at: http://ceur-ws.org/Vol-2212/paper12.pdf.
[15] Tchernykh A., Bychkov I., Feoktistov A., Gorsky S., Sidorov I., Kostromin R., Edelev A., Zorkalzev V., Avetisyan A. Mitigating uncertainty in developing and applying scientific applications in an integrated computing environment. Programming and Computer Software. 2020; 46(8):483–502. DOI:10.1134/S036176882008023X. Available at: https://link. springer.com/article/10.1134/S036176882008023X.
[16] Sholomov L.A. Logicheskie metody issledovaniya diskretnykh modeley vybora [Logical methods for studying choice discrete models]. Moscow: Nauka; 1989: 288. (In Russ.)
[17] Feoktistov A.G., Kostromin R.O., Sidorov I.A., Gorsky S.A., Basharina O.Yu. Digital twins of operation processes for environmentally friendly equipment of infrastructure object. Modern High Technologies. 2021; (1):57–62. (In Russ.)
[18] Maysyuk E.P., Kozlov A.N., Ivanova I.Yu. Influence of technical characteristics of solid fuels at estimation of emissions from small boiler plants. Energy Systems Research. 2018; 1(2):43–50. DOI:10.25729/esr.2018.02.0005. Available at: http://esrj.ru/index.php/esr/article/view/2018.02.0005.
[19] Marinchenko A.Y., Edelev A.V. A formation of the heat pump mathematical models. Proceedings of the 2nd International Workshop on Information, Computation, and Control Systems for Distributed Environments (ICCS-DE). Irkutsk; 2020; (2638):191–200. DOI:10.47350/ICCS-DE.2020.18.
[20] Methodology for calculating greenhouse gas emissions (CO2-equivalent). Self-Regulatory Organization Non-Commercial Partnership “Interregional Alliance of Energy Auditors”. 2022. Available a: thttps://sro150.ru/metodiki/371-metodika-rascheta-vybrosov-parnikovykh-gazov. (äàòà îáðàùåíèÿ 29.05.2022)
[21] Weather forecast: weather in 243 countries of the world. St. Petersburg; 2022. Available at: https: //rp5.ru. (accessed at May 29, 2022) (In Russ.)
[22] Bychkov I.V., Ruzhnikov G.M., Fedorov R.K., Khmelnov A.E., Popova A.K. Digital environmental monitoring technology Baikal natural territory. Proceedings of the 3rd Scientific-Practical Workshop Information Technologies: Algorithms, Models, Systems (ITAMS 2020). Irkutsk; 2020; (2677):1–7. Available at: http://ceur-ws.org/Vol-2677/paper1.pdf.
Bibliography link:
Bychkov I.V., Feoktistov A.G., Kostromin R.O., Basharina O.Y., Sidorov I.A. Simulation of operating environmentally friendly equipment of infrastructure objects in microservice environment // Computational technologies. 2022. V. 27. ¹ 5. P. 30-42
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