2023, issue 2, p. 69-90

Received 20.06.2023; Revised 09.07.2023; Accepted 25.07.2023

Published 28.07.2023; First Online 18.08.2023

https://doi.org/10.34229/2707-451X.23.2.7

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UDC 681.7.08; 6.1

Smart-Systems for Precision Agriculture, Environmental Protection and Healthcare

Volodymyr Romanov ORCID ID favicon Big,   Igor Galelyuka ORCID ID favicon Big,   Volodymyr Hrusha ORCID ID favicon Big,   Hanna Antonova ORCID ID favicon Big,   Oleksandr Voronenko ORCID ID favicon Big,   Anna Kedych ORCID ID favicon Big,   Oleksandra Kovyrova * ORCID ID favicon Big

V.M. Glushkov Institute of Cybernetics of the NAS of Ukraine, Kyiv

* Correspondence: This email address is being protected from spambots. You need JavaScript enabled to view it.

 

Appearance of innovative tools of informatics in the world is determined by development of information-communication technology, microelectronics, sensor and biosensor technologies. Spreading of these technologies on precision agriculture, environmental protection and health care gives opportunity to create smart fields, gardens, greenhouses, forests and parks, and also smart health monitors, which estimate the health state of person as in rehabilitation, so in emergency situations.

Results of research of authors in the development of new information technologies and creation of main components of the smart systems for different purposes on this base are shows in this paper.

Main requirements for knowledge bank for precision agriculture and ecological monitoring are defined. Main principles of creating knowledge bank on base of requirements are proposed. The typical smart system models and their development stages are considered. Structure of wireless multilevel networks for the estimation of state of biological objects of different origin and their nodes are described. Developed sensor networks and smart systems for agriculture are considered. Structure of proposed smart system for agriculture and ecological monitoring is given. Approaches for chlorophyll fluorescence induction curves analysis are studied. Results of network testing for the estimation of the autonomous work time of network nodes and possible errors are given.

Wireless sensor network and smart system for remote medical monitoring are described. Diagnostic smart systems for estimation of quality of life are considered. Medical communicator, computer device on base of tablet computer, was used for their development. The short form of Survey Instrument (SF-36) for life quality estimation and abnormal uterine bleeding questionnaire, which was developed in State Scientific Institution "Center for Innovative Medical Technologies of the National Academy of Sciences of Ukraine", were embedded in communicator. STEPS questionnaire which was designed for epidemiological monitoring of the prevalence of noncommunicable diseases and their risk factors in the target subpopulations could be added to communicator.

Development of smart systems for estimation of quality of life and prevalence of noncommunicable diseases was made in cooperation with R.E. Kavetsky Institute of Experimental Pathology, Oncology and Radiobiology NAS of Ukraine (department of research management and innovation), Chebotarev Institute of Gerontology of the National Academy of Medical Sciences of Ukraine, Center for Innovative Medical Technologies of the National Academy of Sciences of the Ukraine.

 

Keywords: wireless sensor network, precision agriculture, chlorophyll fluorescence induction, express-diagnostics of plant state, quality of life, SF-36.

 

Cite as: Romanov V., Galelyuka I., Hrusha V., Antonova H., Voronenko O., Kedych A., Kovyrova O. Smart-Systems for Precision Agriculture, Environmental Protection and Healthcare. Cybernetics and Computer Technologies. 2023. 2. P. 69–90. https://doi.org/10.34229/2707-451X.23.2.7

 

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