Research OF Complex Processes Based on Step-By-Step Modeling

Authors

DOI:

https://doi.org/10.15802/stp2021/252704

Keywords:

technological process, simulation programming, technological process modeling, mathematical modeling

Abstract

Purpose. When solving practical problems that require the creation and further analysis of the model, an important criterion is the labour intensity of modeling. In this regard, the article is aimed at formalizing the modeling process and using the method of step-by-step modeling for the design of technological processes. This approach allows you to design processes and tasks according to the following stages: physical modeling, mathematical modeling, discrete computer modeling and simulation. Methodology. To solve the problem, a methodology of step-by-step modeling is used. The simulation involves 3 stages and uses the decomposition algorithm, i. e. considers the problem from global to detailed. At the first stage of this implementation, the necessary information is collected for the experiment. This information is presented in the form of statistics. In the second stage, further processing takes place, which is performed by checking the compliance of the input data and the process with the question of how this process should be performed. The last stage is the simulation of passages of this fragment, which is represented by a chain of transitions, obtaining statistics of time efficiency of this process, weaknesses of the process and the ability to compare the results obtained during modeling and in the real process, as well as the ability to predict future results and actions. Findings. The technique can be used to study complex technological processes in the enterprise. It allows modeling of complex processes to obtain information about the time efficiency of the technological operation, finding weaknesses in it and patterns in the occurrence of random events that may affect the operation. Using this approach can be very effective in the systems that require constant real-time monitoring, as this tool can be modified by adding sensor kits that will constantly send information to the system or equip an additional system that will provide ready-made information packets. Originality. The method of step-by-step modeling of representation has been improved, which consists in the simultaneous use of physical, mathematical and simulation modeling of complex processes with a set of stages of their implementation. Practical value. The proposed technique is designed for step-by-step modeling of the technological process with the subsequent construction of simulation programming.

References

Bobrovsky, V. I., Kozachenko, D. N., Vernigora, R. V., & Malashkin, V. V. (2015). Funktsionalnoe modeliro-vanie raboty zheleznodorozhnykh stantsiy: monografiya. Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan. Dnepropetrovsk. (in Russian)

Glushkov, V. M. (1962). Sintez tsifrovykh avtomatov. Moscow: Fizmatlit. (in Russian)

Gorbova, O. V. (2016). Formalization of the Technological Processes at Railway Stations Based on the Step-by-Step Modeling. Science and Transport Progress, 5(83), 71-80. DOI: https://doi.org/10.15802/stp2019/181850 (in Ukrainian)

Dozortsev, V. M. (1996). Dinamicheskoe modelirovanie v optimalnom upravlenii i avtomatizirovannom obuchenii operatorov tekhnologicheskikh protsessov. Ch. 2. Kompyuternye trenazhery realnogo vremni. Instruments and Systems, 8, 41-50. (in Russian)

Kozachenko, D. M., Vernigora, R. V., & Korobyova, R. G. (2008). The Software Package for Simulation of Railway Stations Based on Plan-Schedule. Railway Transport of Ukraine, 4, 18-20. (in Ukrainian)

Kozachenko, D. N., Vernigora, R. V., & Malashkin, V. V. (2014). Automated formation of functional models of railway stations. Transport systems and transportation technologies, 8, 65-73. (in Russian)

Kozachenko, D. M. (2013). Object-oriented model of railway stations operation. Science and Transport Progress, 4(46), 47-55. DOI: https://doi.org/10.15802/stp2013/16570 (in Russian)

Leonenkov, A. V. (2002). Samouchitel UML. Saint Petersburg: BHV-Petersburg. (in Russian)

Malkov, M. V., Oleynik, A. G., & Fedorov, A. M. (2010). Modeling of technological processes: methods and ex-perience. Transactions Kоla Science Centre, 3(3), 93-101. (in Russian)

Petrosov, D. A., & Ignatenko, V. A. (2017). Step-by-modeling of technological processes with use of intelligent structural-parametric synthesis. Fundamental research, 12(1), 97-102. DOI: https://doi.org/10.17513/fr.41986 (in Russian)

Rozin, M. D., & Svichkarov, V. P. (2012). Problemy sistemnogo modelirovaniya slozhnykh protsessov sotsialnogo vzaimodeystviya. Inzhenernyy vestnik Dona, 2, 609-618. (in Russian)

Bianco, Vieri del, Lavazza, L., & Mauri, M. A formalization of UML statecharts for real-time software model-ing. Retrieved from https://cutt.ly/QeZxM3q (in English)

Gorbova, O. V. (2015). Modeling Work of Sorting Station Using UML. Science and Transport Progress, 1(55), 129-138. DOI: https://doi.org/10.15802/stp2015/38260 (in English)

Harel, D. (1987). Statecharts: a visual formalism for complex systems. Science of Computer Programming, 8(3), 231-274. DOI: https://doi.org/10.1016/0167-6423(87)90035-9 (in English)

Harel, D. (1988). Statecharts: A visual formalisms. Communications of the ACM, 31(5), 514-530. DOI: https://doi.org/10.1145/42411.42414 (in English)

Silva, M., Colom, J.-M., Julvez, J., Mahulea, C., Schuppen, J. H., van, Su, R., … & Darondeau, P. (2007). On Modeling of Hierarchical and Distributed Discrete-Event Systems. The DISC Project Perspective. (in English)

Zimmermann, A., & Trowitzsch, J. Eine Quantitative Untersuchung des European Train Control System mit UML State Machines. Retrieved from https://cutt.ly/HeZxV5r (in German)

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Published

2021-10-18

How to Cite

Horbova, O. V., & Murkovych, N. S. (2021). Research OF Complex Processes Based on Step-By-Step Modeling. Science and Transport Progress, (5(95), 51–59. https://doi.org/10.15802/stp2021/252704

Issue

No. 5(95) (2021)

Section

INFORMATION AND COMMUNICATION TECHNOLOGIES AND MATHEMATICAL MODELING

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