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System of Integrated Simulation of Spread of Hazardous Factors of Fire and Evacuation of People from Indoors

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Abstract

We present an integrated mathematical model and its implementation in the form of a software and information complex developed for joint modeling of the spread of dangerous fire factors and spontaneous evacuation of people from premises of complex configuration. The propagation of fire, heat, and smoke is modeled based on the principle of cellular automata. To simulate the evacuation process, we have developed and used a multiagent model that takes into account the physical characteristics and behavior of people during collisions.

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Authors and Affiliations

  1. Trapeznikov Institute of Control Sciences, Russian Academy of Sciences, Moscow, 117997, Russia

    A. D. Tsvirkun, A. F. Rezchikov & L. Yu. Filimonyuk

  2. Saratov Scientific Center of the Russian Academy of Sciences, Saratov, 410028, Russia

    A. A. Samartsev, V. A. Ivashchenko, A. S. Bogomolov & V. A. Kushnikov

Authors
  1. A. D. Tsvirkun
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  2. A. F. Rezchikov
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  3. L. Yu. Filimonyuk
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  4. A. A. Samartsev
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  5. V. A. Ivashchenko
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  6. A. S. Bogomolov
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  7. V. A. Kushnikov
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Corresponding authors

Correspondence to A. D. Tsvirkun, A. F. Rezchikov, L. Yu. Filimonyuk, A. A. Samartsev, V. A. Ivashchenko, A. S. Bogomolov or V. A. Kushnikov.

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Translated by V. Potapchouck

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Tsvirkun, A.D., Rezchikov, A.F., Filimonyuk, L.Y. et al. System of Integrated Simulation of Spread of Hazardous Factors of Fire and Evacuation of People from Indoors. Autom Remote Control 83, 692–705 (2022). https://doi.org/10.1134/S0005117922050034

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  • DOI: https://doi.org/10.1134/S0005117922050034

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