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Modeling of transportation and technological processes in automated systems

https://doi.org/10.21821/2309-5180-2024-16-1-154-162

Abstract

The purpose of the study is to create a problem-oriented model of transport and technological processes in automated systems. To achieve this goal, it is necessary to develop methodological aspects of creating an automated modeling system. The content of the basic principles of problem-oriented modeling in the study of an integrated automated system for managing stocks and transport and technological processes is revealed in the paper. At the same time, methodological aspects of creating automated modeling systems, namely, a conceptual mathematical model for the analysis and standardization of technical and economic indicators are considered. The functioning of logistics systems, namely, system modeling (supply — transport) is also considered. The problems of interaction and relationships, optimization of resource flows, and increasing the efficiency of management decisions making have been solved. It is shown that modeling resource flows involves adjustments through iterative redistribution of interregional and intraregional supplies among suppliers and consumers. Combining product items into one delivery leads to savings in stocks formation costs by reducing the number of orders. To create effective automated control systems, it is necessary to study in detail the primary object — the logistics and technical support system itself. The creation of applied mathematical and software is a promising direction for solving this problem and developing it as an automated modeling system. In this regard, when creating such automated control systems, it is most advisable to use a model-oriented approach, which is based on the principles of system analysis, standardization, classification and modularity. Thus, it is shown that the use of the problem-oriented approach to creating an automated modeling system makes it possible to reduce the labor intensity of its development and implementation, to provide the opportunity to unify algorithms for solving a problem, but also to apply standard methods for processing experimental results.

About the Authors

K. P. Goloskokov
Admiral Makarov State University of Maritime and Inland Shipping
Russian Federation

Goloskokov, Konstantin P. — Dr. of Technical Sciences, associate professor

5/7 Dvinskaya Str., St. Petersburg, 198035



N. B. Glebov
Admiral Makarov State University of Maritime and Inland Shipping
Russian Federation

Glebov, Nikolay B. — PhD, associate professor

5/7 Dvinskaya Str., St. Petersburg, 198035



A. A. Astapkovich
Admiral Makarov State University of Maritime and Inland Shipping
Russian Federation

Astapkovich, Aleksey A. — Postgraduate

5/7 Dvinskaya Str., St. Petersburg, 198035



References

1. Ilchenko, Anna A., Denis A. Akmaykin, and Anastasia V. Gams. “Automated approach for solving the problem of determining the maritime autonomous surface ship operation area.” Vestnik Gosudarstvennogo universiteta morskogo i rechnogo flota imeni admirala S. O. Makarova 14.4 (2022): 508–518. DOI: 10.21821/2309-5180-2022-14-4-508-518.

2. Fedorovskaya, Nadezhda K., and Konstantin Yu. Fedorovskiy. “Estimating the efficiency of ship power plants cooling systems taking into account the environmental factor.” Vestnik Gosudarstvennogo universiteta morskogo i rechnogo flota imeni admirala S. O. Makarova 13.4 (2021): 559–568. DOI: 10.21821/2309-5180-2021-13-4-559-568.

3. Kuznetsov, A., A. Galin, S. Valkova, and A. Sampiev. “Technological transformation of universal berths into small container terminals.” Transport business of Russia 2 (2022): 243–249.

4. Tsarev, R. Yu., A. N. Pupkov, M. A. Ognerubova, M. V. Serzhantova, and N. A. Beschastnaya. “Model of analysis of distributed computing systems reliability.” The Siberian Aerospace Journal 1(47) (2013): 86–91.

5. Pavlovskaya, O. O. “Static methods of assessment of software.” Bulletin of the South Ural State University. Series, Computer technologies, automatic control, radio electronics 26(159) (2009): 35–37.

6. Grazhdantsev, E. V., M. A. Rusakov, O. I. Zavyalova, and R. Ju. Tsarev. “Practical realization of reliability analysis of software architecture.” The Siberian Aerospace Journal 1(18) (2008): 37–40.

7. Tsarev R. Yu., E. N. Shtarik, and A. V. Shtarik. “Toward the problem of estimation of the complex software system reliability.” Journal of Siberian Federal University. Engineering & Technologies 8.1 (2015): 33–47.

8. Kuznetsov, Alexander Lvovich, Alexander Valentinovich Galin, Svetlana Sergeevna Valkova, and Adam Mihaylovich Sampiev. “Analysis of seaport bulk cargo warehouse capacity by using simulation modeling.” Vestnik of Astrakhan State Technical University. Series: Marine engineering and technologies 3 (2022): 82–89. DOI: 10.24143/2073-1574-2022-3-82-89.

9. Galin, A., and A. Slican. “Development of LCL shipments in a situation of rising cost of container transportation.” Transport business of Russia 3 (2022): 117–119. DOI: 10.52375/20728689_2022_3_117.

10. Slican, A., A. Galin, and E. Vinogradova. “Features of determining the amount of loaded cargo on riversea vessels.” Transport business of Russia 4 (2022): 124–126. DOI: 10.52375/20728689_2022_4_124.

11. Gaskarov, D.V., K. P. Goloskokov, and A. V. Shkabardnya. “Mathematical programming in discriminant analysis for forecasting.” Avtomatika i Telemekhanika 7 (1988): 174–181.

12. Goloskokov, K.P., and K. A. Davydov. “Mathematical model of technology of storekeeping of the company.” Upravlenie ekonomicheskimi sistemami 2(38) (2012): 9.

13. Goloskokov, K. P. “Prognozirovanie i otsenka tekhnicheskogo sostoyaniya slozhnykh system.” Nauchnotekhnicheskie vedomosti Sankt-Peterburgskogo gosudarstvennogo politekhnicheskogo universiteta 1(53) (2008): 164–168.

14. Goloskokov, K. P., N. K. Nesterenko, and M. Y. Chirkova. “Increase of efficiency of activity of the industrial enterprise.” Audit and financial analysis 1 (2014): 331–335.

15. Brusakova, I. A., and K. P. Goloskokov. “Mathematical model of functional reliability of the automated control systems.” Vestnik INZhEKONa. Seriya: Tekhnicheskie nauki 8 (2010): 48–51.

16. Nyrkov, A. P., A. A. Nyrkov, S. S. Sokolov, and A. A. Shnurenko. Obespechenie bezopasnosti ob”ektov informatizatsii transportnoi otrasli. Edited by A. P. Nyrkov. SPb.: Izd-vo Politekhn. un-ta, 2015.

17. Nyrkov, A. P., S. S. Sokolov, and A. V. Bashmakov. “Technique of designing safe information systems on transport.” Information Security Problems. Computer Systems 3 (2010): 58–61.

18. Lyulchenko, Andrei Nikolaevich, Anatoliy Pavlovich Nyrkov, and Viktor Grigorievich Shved. “Model of the system providing information security on transport.” Vestnik Gosudarstvennogo universiteta morskogo i rechnogo flota imeni admirala S. O. Makarova 5(33) (2015): 184–193.


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For citations:


Goloskokov K.P., Glebov N.B., Astapkovich A.A. Modeling of transportation and technological processes in automated systems. Vestnik Gosudarstvennogo universiteta morskogo i rechnogo flota imeni admirala S. O. Makarova. 2024;16(1):154-162. (In Russ.) https://doi.org/10.21821/2309-5180-2024-16-1-154-162

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ISSN 2309-5180 (Print)
ISSN 2500-0551 (Online)