Building a model and an algorithm for modeling the movement of people carrying goods when they are evacuated from premises

Authors

DOI:

https://doi.org/10.15587/1729-4061.2021.233916

Keywords:

heterogeneous flows of people, individual-flow movement, optimization by group of variables, nonlinear programming

Abstract

Evacuation is often the only way to save a person who is in a life-threatening situation. At present, evacuation software is used to simulate the movement of human flows, which does not always reflect the real processes of their movement. Therefore, it is a relevant task to build models for modeling the movement of human flows for different types of emergencies, different categories of human movement, and various spatial forms of their representation. Such a task arises when evacuating people from premises for various functional purposes.

During evacuation, people often carry some goods. When people move carrying some goods, their horizontal projection takes a more complex shape than an ellipse or circle considered in earlier studies. Moreover, in practice, there is often a task to model the movement of people taking into consideration the maximum permissible distances between them.

This paper reports the new quasi-phi functions of interaction between the ellipse and rectangle accounting for the maximum allowable distances between them. The proposed mathematical apparatus has made it possible to formalize the interaction between objects, thereby enabling the construction of a well-substantiated mathematical model, as well as the methods and algorithms for modeling the movement of people carrying some goods.

The possibility to simulate the movement of people with certain objects has shown taking into consideration the maximum permissible distances between them. A test example of the movement of people along four corridors was simulated, in each of which there were 28 people subsequently merging into one flow. Given the uniform distribution of three types of cargo: «backpacks», «suitcases», and «bags on wheels», the movement slowed down by about 4 %. When half of the evacuees had «bags on wheels» that can move away from people at arm’s length, the slowdown was about 6 %.

Author Biographies

Alexander Pankratov, A. Pidhornyi Institute of Mechanical Engineering Problems of the National Academy of Sciences of Ukraine

Doctor of Technical Sciences, Senior Researcher

Department of Mathematical Modeling and Optimal Design

Valentina Komyak, National University of Civil Defence of Ukraine

Doctor of Technical Sciences, Professor

Department of Physical and Mathematical Sciences

Kyazimov Tahir oglu Kyazim, Academy of the Ministry of Emergency Situations of the Republic of Azerbaijan

PhD

Department of Specialized Fire Safety Disciplines

Vladimir Komyak, National University of Civil Defence of Ukraine

PhD

Department of Management and Organization in the Field of Civil Protection

Olexandr Tarasenko, National University of Civil Defence of Ukraine

Doctor of Technical Sciences, Senior Researcher

Department of Physical and Mathematical Sciences

Oleksiy Antoshkin, National University of Civil Defence of Ukraine

PhD

Department of Automated Security Systems and Information Technologies

Iurii Mishcheriakov, Kharkiv National University of Radio Electronics

PhD

Department of Systems Engineering

Mykhailo Dolhodush, Head Directorate of the DSNS of Ukraine near the Kharkiv Region

PhD

Department for Planning, Analytical and Documentary Security

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Published

2021-06-29

How to Cite

Pankratov, A., Komyak, V., Kyazim, K. T. oglu, Komyak, V., Tarasenko, O., Antoshkin, O., Mishcheriakov, I., & Dolhodush, M. (2021). Building a model and an algorithm for modeling the movement of people carrying goods when they are evacuated from premises. Eastern-European Journal of Enterprise Technologies, 3(4 (111), 43–50. https://doi.org/10.15587/1729-4061.2021.233916

Issue

Vol. 3 No. 4 (111) (2021): Mathematics and Cybernetics - applied aspects

Section

Mathematics and Cybernetics - applied aspects

License

Copyright (c) 2021 Alexander Pankratov, Valentina Komyak, Kyazimov Tahir oglu Kyazim, Vladimir Komyak, Olexandr Tarasenko, Oleksiy Antoshkin, Iurii Mishcheriakov, Mykhailo Dolhodush

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