RESEARCH RESULTS OF THE CYBER-PHYSICAL SYSTEM ON ONLINE-MONITORING OF AIR HUMIDITY IN GREENHOUSES GROWING AREA
DOI:
https://doi.org/10.32782/IT/2023-1-8Keywords:
cyber-physical system, monitoring, humidity, greenhouse, growing area, structuralalgorithmic organizationAbstract
Relevance. Nowadays, one of the global world problems, which has been increasing significantly recently, is the need to ensure of food-security and year-round availability of food products for people in different countries of the world. This problem requires a comprehensive solution via generating a scientifically based approach in various directions, that stimulate the optimization of long-term sustainability of agricultural production, including through rational use of resources and work planning during the cultivation, storage and transportation of agricultural products. Therefore, the scientific and applied problem of this article is relevant and consists in the development of the theory of cyber-physical systems construction for agrotechnical purpose due to the substantiation of computer-oriented methods and models of comprehensive aggregation and intellectual transformation of distributed measurement data of the air humidity of industrial greenhouses growing areas. The main purpose of the article is the development of scientific approaches to further modernization of Industry 4.0 systems for agrotechnical purposes due to the substantiation of the structural and algorithmic organization of the cyber-physical system on non-destructive online monitoring of air humidity of industrial greenhouses growing areas. The research object is non-stationary processes of aggregation, transmission and interpretation of distributed measurement data of the air humidity of industrial greenhouses growing areas. The research subject is methods and technologies on non-destructive online monitoring of the air humidity of industrial greenhouses growing areas. Conclusions. The important scientific and applied task of the development of scientific approaches to the further modernization of Industry 4.0 systems for agrotechnical purpose has been solved due to the substantiation of the structural and algorithmic organization of the cyber-physical system on non-destructive online monitoring of the air humidity of industrial greenhouses growing areas.
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