Refinement of three-layer model of a damaged human body for the case of changing the moisture of the banding material

Authors

DOI:

https://doi.org/10.15587/1729-4061.2023.277946

Keywords:

non-invasive diagnostics, plaster cast, radiothermal mapping, regression analysis, quality indicators

Abstract

The object of study is a three-layer model of a damaged human body.

In the course of the study, it was found that the generally accepted three-layer model of a damaged human body is built, in particular, on the assumption that the characteristics of dressings remain unchanged over time. Therefore, the vast majority of modern research in the field of passive radiometry requires the removal of such materials from the human body during the measurement or considers their characteristics to be unchanged and insignificant. Questions of a possible change in the results of measuring the radiation of the human body due to the use of plaster casts of varying degrees of humidity remain almost unexplored.

As a result of the study, the mathematical three-layer model of the damaged human body was refined. An element was introduced into the model that describes the dependence of the attenuation of radio wave energy on the relative humidity of the plaster cast. The refined model makes it possible to increase the accuracy of measuring the temperature of the human body, taking into account the time of applying a plaster cast to it. Unlike the existing ones, the proposed model is based on an experimental study that simulates the measurement of the radiation of a human body with a plaster cast of different degrees of humidity. To refine the model, the obtained experimental data were processed by regression analysis methods.

The results of processing the experimental data made it possible to establish the specific type and value of the coefficients of the desired dependence.

The use of the obtained results of the study proves the possibility of remote non-invasive express diagnostics of the state of the human body in the presence of plaster-gauze bandages.

Providing such an opportunity allows disaster medicine workers to increase the ability to fulfill the so-called “golden hour rule”, as well as to clarify the requirements for a medical radiothermal mapping system

Author Biographies

Maksym Ievlanov, Kharkiv National University of Radio Electronics

Doctor of Technical Science, Associate Professor

Department of Information Control Systems

Serhii Chumachenko, National University of Food Technologies

Doctor of Technical Science, Senior Researcher

Department of Information Technologies, Artificial Intelligence and Cyber Security

Oleksandr Fursenko, Institute of Public Administration and Research in Civil Protection

PhD

Department of Innovations, Information Activity in Education and Training on International Projects

Ihor Cherepnov, State Biotechnological University

PhD, Senior Researcher, Associate Professor

Department of Mechatronics, Life Safety and Quality Management

Volodymyr Kyselov, V. I. Vernadsky Taurida National University

Doctor of Technical Science, Professor, Director

Educational and Scientific Institute of Municipal Management and City Economy

Oleksandr Guida, V. I. Vernadsky Taurida National University

PhD

Department of Computer and Information Technologies

Sergii Furtat, V. I. Vernadsky Taurida National University

Senior Lecturer

Department of Automated Management of Technological Processes

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Refinement of three-layer model of a damaged human body for the case of changing the moisture of the banding material

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Published

2023-04-29

How to Cite

Ievlanov, M., Chumachenko, S., Fursenko, O., Cherepnov, I., Kyselov, V., Guida, O., & Furtat, S. (2023). Refinement of three-layer model of a damaged human body for the case of changing the moisture of the banding material. Eastern-European Journal of Enterprise Technologies, 2(5 (122), 38–45. https://doi.org/10.15587/1729-4061.2023.277946

Issue

Vol. 2 No. 5 (122) (2023): Applied physics

Section

Applied physics

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Copyright (c) 2023 Maksym Ievlanov, Serhii Chumachenko, Oleksandr Fursenko, Ihor Cherepnov, Volodymyr Kyselov, Oleksandr Guida, Sergii Furtat

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