Plant health monitoring: Intelligent systems for environmental geoinformation

D Jamoljon; A Erkin; B Azizdjan; A Jamshid; T Ismat

doi:10.14719/pst.8223

Research Articles

Vol. 12 No. 4 (2025)

Plant health monitoring: Intelligent systems for environmental geoinformation

Jamoljon Djumanov^▸^▾
Erkin Anorboev^▸^▾
Azizdjan Babadjanov^▸^▾
Jamshid Abdurazzakov^▸^▾
Ismat Telyayev ^▸^▾

DOI

https://doi.org/10.14719/pst.8223

Submitted

13 March 2025

Published

24-09-2025 — Updated on 16-10-2025

Versions

16-10-2025 (2)
24-09-2025 (1)

Abstract

This study presents methods for gathering and preprocessing data from observation wells using automated measurement systems. It also incorporates fuzzy logic models for calculations, signal data processing and intelligent analysis of mapping materials. The study also involves the creation of groundwater level distribution maps based on the gathered data. Advanced measurement methods are being explored for experimental and computational applications, leading to the development of technical solutions based on mathematical models. These innovations are crucial for enhancing automated monitoring techniques in hydrogeological regions to predict groundwater levels and quality.

References

1. Djumanov JX. Geoinformation technology and hydrogeology. Tashkent; 2016:28.
2. Djumanov JX. Automatic measurement of sensors for underground water monitoring in the Republic of Uzbekistan. Geology and mineral resources. 2011;4:23-8.
3. Sysoeva SV. Sensors RUS - on the pulse of your pressure. Recommendations for choosing pressure sensors for industry and housing and communal services. Components and technologies. 2008;1:60-2.
4. Sharapov RV. Equipment for autonomous monitoring of groundwater conditions. Fundamental research. 2014;9(1):55-8.
5. Djumanov J, Rajabov F, Abdurashidova K, Xodjaev N. Autonomous wireless sound gauge device for measuring liquid level in well. E3S Web Conf. 2023;401:01063. https://doi.org/10.1051/e3sconf/202340101063
6. Khushvaktov SKh, Mirsoatov AM, Anorboev EA, Mardiev O'B. Automation of measurement and remote transmission of hydrogeological data. Geology and mineral resources. 2019;1:46-8.
7. Djumanov JKh, Anorboev EA, Jamolov XM. Analysis of the hydrogeological conditions of the object in order to conduct automated monitoring of measurements of groundwater parameters. Int J Geol Earth Environ Sci. 2023;13:161-7. http://www.cibtech.org/jgee.htm
8. Masood A, Tariq MAUR, Hashmi MZUR, Waseem M, et al. An overview of groundwater monitoring through point-to-satellite-based techniques. Water. 2022;14:565. https://doi.org/10.3390/w14040565
9. Djumanov JKh, Khushvaktov SKh, Kuchkorov T, Anorboev EA. Automated measuring systems in monitoring the hydrogeological characteristics of aquifers. Science and innovation. 2022;1(6):209-17.
10. Singgih J, Achmad M, Indri-ati. Prototype of water level detection system with wireless. J Theor Appl Inf Technol. 2012;37:52-9.
11. Thuku IT, Ajayi IA. A review on electrical instrumentation techniques applied in groundwater level determination. Int J Eng Sci Res Technol. 2018;28-38. https://doi.org/10.5281/zenodo.1407686
12. Nazirova ON. Experience of implementation of hydrodynamic regime autonomous complex "RADIUS". Exploration and protection of mineral resources. 2002;6:48-50.
13. Djumanov JKh, Khushvaktov SKh, Kuchkorov T, Anorboev EA. Improvement hydroregime characteristics control of groundwater in monitoring wells using information systems. 2022 Int Conf Inf Sci Commun Technol (ICISCT). Tashkent; 2022.
14. Djumanov JKh, Anorboev EA, Babadjanov A, Telyayev I, Abdurazzakov JT. Intellectual support of geoinformation and technical system of hydrosphere monitoring of measuring wells. In: Digital transformation and artificial intelligence: problems, innovations and trends. I Int Sci Pract Conf. 2024:121-4.
15. Lin Wu CY, Bloom M, Cox JA, Miller M. Rotation scale and translation resilient public watermarking for images. IEEE Trans Image Process. 2024;10(5):767-82. https://doi.org/10.1109/83.918569
16. Djumanov JX, Anorboev EA, Jamolov XM. Creating a remote data transmission device that determines the level of underground water and current conductivity from monitoring wells. J Descendants of Muhammad al-Khorazmi. 2023;1(23):113-4.

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How to Cite

Jamoljon D, Erkin A, Azizdjan B, Jamshid A, Ismat T. Plant health monitoring: Intelligent systems for environmental geoinformation. Plant Sci. Today [Internet]. 2025 Oct. 16 [cited 2025 Nov. 26];12(4). Available from: https://horizonepublishing.com/index.php/PST/article/view/8223

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1. Djumanov JX. Geoinformation technology and hydrogeology. Tashkent; 2016:28.

[2] 2. Djumanov JX. Automatic measurement of sensors for underground water monitoring in the Republic of Uzbekistan. Geology and mineral resources. 2011;4:23-8.

[3] 3. Sysoeva SV. Sensors RUS - on the pulse of your pressure. Recommendations for choosing pressure sensors for industry and housing and communal services. Components and technologies. 2008;1:60-2.

[4] 4. Sharapov RV. Equipment for autonomous monitoring of groundwater conditions. Fundamental research. 2014;9(1):55-8.

[5] 5. Djumanov J, Rajabov F, Abdurashidova K, Xodjaev N. Autonomous wireless sound gauge device for measuring liquid level in well. E3S Web Conf. 2023;401:01063. https://doi.org/10.1051/e3sconf/202340101063

[6] 6. Khushvaktov SKh, Mirsoatov AM, Anorboev EA, Mardiev O'B. Automation of measurement and remote transmission of hydrogeological data. Geology and mineral resources. 2019;1:46-8.

[7] 7. Djumanov JKh, Anorboev EA, Jamolov XM. Analysis of the hydrogeological conditions of the object in order to conduct automated monitoring of measurements of groundwater parameters. Int J Geol Earth Environ Sci. 2023;13:161-7. http://www.cibtech.org/jgee.htm

[8] 8. Masood A, Tariq MAUR, Hashmi MZUR, Waseem M, et al. An overview of groundwater monitoring through point-to-satellite-based techniques. Water. 2022;14:565. https://doi.org/10.3390/w14040565

[9] 9. Djumanov JKh, Khushvaktov SKh, Kuchkorov T, Anorboev EA. Automated measuring systems in monitoring the hydrogeological characteristics of aquifers. Science and innovation. 2022;1(6):209-17.

[10] 10. Singgih J, Achmad M, Indri-ati. Prototype of water level detection system with wireless. J Theor Appl Inf Technol. 2012;37:52-9.

[11] 11. Thuku IT, Ajayi IA. A review on electrical instrumentation techniques applied in groundwater level determination. Int J Eng Sci Res Technol. 2018;28-38. https://doi.org/10.5281/zenodo.1407686

[12] 12. Nazirova ON. Experience of implementation of hydrodynamic regime autonomous complex "RADIUS". Exploration and protection of mineral resources. 2002;6:48-50.

[13] 13. Djumanov JKh, Khushvaktov SKh, Kuchkorov T, Anorboev EA. Improvement hydroregime characteristics control of groundwater in monitoring wells using information systems. 2022 Int Conf Inf Sci Commun Technol (ICISCT). Tashkent; 2022.

[14] 14. Djumanov JKh, Anorboev EA, Babadjanov A, Telyayev I, Abdurazzakov JT. Intellectual support of geoinformation and technical system of hydrosphere monitoring of measuring wells. In: Digital transformation and artificial intelligence: problems, innovations and trends. I Int Sci Pract Conf. 2024:121-4.

[15] 15. Lin Wu CY, Bloom M, Cox JA, Miller M. Rotation scale and translation resilient public watermarking for images. IEEE Trans Image Process. 2024;10(5):767-82. https://doi.org/10.1109/83.918569

[16] 16. Djumanov JX, Anorboev EA, Jamolov XM. Creating a remote data transmission device that determines the level of underground water and current conductivity from monitoring wells. J Descendants of Muhammad al-Khorazmi. 2023;1(23):113-4.