AUTHOR(S) / АУТОР(И): Lukyanov A.D. 
, Donskoy Danila Yu. , Nemanja Miletic , Donskoy Dmitry Yu. , Dudinov I.O
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DOI: https://doi.org/10.46793/SBT26.089L
ABSTRACT / САЖЕТАК:
Modern plant cultivation methods inherently should incorporate digital monitoring and control systems to enhance the efficiency of agricultural enterprises. Monitoring and precise measurement of the UV component of solar radiation is an important issue, yet it is often ignored in common weather stations and monitoring systems. UV radiation affects plant physiology, pollinator activity, risks of disease emergence, etc. Due to the lack of data on solar activity in this spectral range, it is impossible to correctly adapt protective measures or, conversely, supplemental lighting using UV lamps. Their integration into closed agricultural cultivation systems requires the optimization of algorithms. Existing UV radiation measurement systems are costly and do not solve the problem of continuous monitoring over large areas with the widespread use of artificial lighting sources. Thus, the relevant task is the creation of a distributed system for monitoring both solar and artificial UV radiation.
KEYWORDS / КЉУЧНЕ РЕЧИ:
UV radiation, monitoring, sensor, ESP32, model
ACKNOWLEDGEMENT / ПРОЈЕКАТ:
The work was carried out within the framework of the project „Mathematical Modeling and Algorithms for Simulating Plant Growth Based on an Automated Cartographic System“ (FZNE2024-0006).
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