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Communication Papers of the 18th Conference on Computer Science and Intelligence Systems

Annals of Computer Science and Information Systems, Volume 37

Mathematical Modeling of Water Regimes on Drained Lands

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DOI: http://dx.doi.org/10.15439/2023F5023

Citation: Communication Papers of the 18th Conference on Computer Science and Intelligence Systems, M. Ganzha, L. Maciaszek, M. Paprzycki, D. Ślęzak (eds). ACSIS, Vol. 37, pages 195200 ()

Full text

Abstract. The model of the dynamics of the groundwater level in the area between the drains during pressure regulation in the drains in the conditions of a three-layer soil structure is proposed and implemented. Having the connection between groundwater level and humidity in the aeration zone established on the basis of the conducted experiments, the issue of ensuring the necessary humidity in the aeration zone within the root system is resolved. As a result of the regulation of GWL in different modes (passive reduction and humidification) taking into account natural conditions, in particular, based on the received database on the amount of precipitation, the necessary parameters were obtained that characterize the water regime in the aeration zone. The analysis of the obtained results allows for establishing and proposing more effective resource-saving modes of moistening under the condition of a sufficient supply of moisture to the root layer. In the conducted experiments, the accumulated precipitation in the active layer (0-0.6 m) of the soil in the mode of passive reduction of GWL, when an accumulative capacity for moisture retention is formed in the

References

  1. Alfonso, L., Lobbrecht, A., Price, R. (2010) Optimization of water level monitoring network in polder systems using information theory. Water Resources Research, 46 (12), p. 1–13.
  2. Basharin D, Polonsky A, Stankunavichus G. (2016) Projected precipitation and air temperature over Europe using a performance-based selection method of CMIP5 GCMs. Journal of Water and Climate Change. 2016;7(1), p.103–113.
  3. Dolid M.А. (1990) Optimal length conducting network of polder systems of Polissya of Ukraine. Hydromelioration and hydro technical construction: Lviv , p. 17-27.
  4. Kuzmych L., Voropay G., Moleshcha N., Babitska O. (2021): Improving water supply capacity of drainage systems at humid areas in the changing climate. Archives of Hydro-Engineering and Environmental Mechanics. Vol. 68. No. 1: 29–40.
  5. Kuzmych,L., Furmanets,O., Usatyi,S., Kozytskyi,O., Mozol,N., Kuzmych,A.,Polishchuk,V. & Voropai,H.(2022).Water Supply of the Ukrainian Polesie Ecoregion Drained Areas in Modern Anthropogenic Climate Changes. Archives of Hydro-Engineering and Environmental Mechanics,69(1) 79-96. https://doi.org/10.2478/heem-2022-0006
  6. Schultz Bart (2008) Water management and flood protection of the polders in the Netherlands under the impact of climate change and man-induced changes in land use. Journal of water and land development, No. 12, p.71–94.
  7. Shang, S.H. (2014) A general multi-objective programming model for minimum ecological flow or water level of inland water bodies. Journal of Arid Land, 7 (2), p. 166-176.
  8. Su, X., Chiang, P., Pan, S., Chen, G., Tao, Y., Wu, G., Wang, F., Cao, W. (2019) Systematic approach to evaluating environmental and ecological technologies for wastewater treatment. Chemosphere, 218, p. 778-792.
  9. Van Overloop, P.J. (2006) Drainage control in water management of polders in the Netherlands. Irrigation and Drainage Systems, 20 (1), p. 99-109.
  10. Andrić I., Koc M. and Al-Ghamdi S. G. 2019 A review of climate change implications for built environment: Impacts, mitigation measures and associated challenges in developed and developing countries J. Clean. Prod. 211 83-102
  11. Korobiichuk I., Kuzmych L., Kvasnikov V., 2019. The system of the assessment of a residual resource of complex technical structures, MECHATRONICS 2019: Recent Advances Towards Industry 4.0, 350–357. https://doi.org/10.1007/978-3-030-29993-4-43.
  12. Ahmed M. R., Hassan Q. K., Abdollahi M. and Gupta A. 2020 Processing of near real time land surface temperature and its application in forecasting forest fire danger conditions Sensors 20 984
  13. Kuzmych L. (2016). Currentr trends in creating water systems for measuring of mechanical quantities. Collection of scientific works of the OSATRQ. No 1(8). P. 95-99 https://doi.org/10.32684/2412-5288-2016-1-8-95-99
  14. Rózsás Á., Kovács N., Gergely Vigh L. and Sýkora M. (2016). Climate change effects on structural reliability in the Carpathian Region Q. J. Hungarian Meteorol. Serv. 120 103-25
  15. Chen K., Blong R. and Jacobson C. (2003). Towards an integrated approach to natural hazards risk assessment using GIS: With reference to bushfires Environ. Manage. 31 546-60
  16. Rokochinskiy, A., Kuzmych, L., Volk, P. (Eds.). (2023). Handbook of Research on Improving the Natural and Ecological Conditions of the Polesie Zone. IGI Global. https://doi.org/10.4018/978-1-6684-8248-3
  17. Rokochinskiy A., Volk P., Kuzmych L., Turcheniuk V., Volk L. and Dudnik A.
  18. "Mathematical Model of Meteorological Software for Systematic Flood Control in the Carpathian Region," 2019 IEEE International Conference on Advanced Trends in Information Theory (ATIT), pp. 143-148, http://dx.doi.org/10.1109/ATIT49449.2019.9030455
  19. Yakymchuk A., Kuzmych L., Skrypchuk P., Kister A., Khumarova N., Yakymchuk Y.. (2022). Monitoring in Ensuring Natural Capital Risk Management: System of Indicators of Socio-Ecological and Economic Security. 16th International Conference Monitoring of Geological Processes and Ecological Condition of the Environment, Nov 2022, Volume 2022, p.1 – 5. http://dx.doi.org/https://doi.org/10.3997/2214-4609.2022580047
  20. Kuzmych L., Voropai H. (2023). Enviornmentally Safe and resource-saving water regulation technologies on drained lands. Handbook of Research on Improving the Natural and Ecological Conditions of the Polesie Zone. IGI Global of Timely Knowledge. Hershey, Pennsylvania 17033-1240, USA. 2023. P. 75-96. https://doi.org/10.4018/978-1-6684-8248-3.ch005
  21. Kuzmych L, Yakymchuk A (2022). Environmental sustainability: economical and organizational aspects of WEF Nexus. 16th International Conference Monitoring of Geological Processes and Ecological Condition of the Environment, Nov 2022, p.1 – 5. http://dx.doi.org/https://doi.org/10.3997/2214-4609.2022580009
  22. Prykhodko N., Koptyuk R., Kuzmych L., Kuzmych A. (2023). Formation and predictive assessment of drained lands water regime of Ukraine Polesie Zone. Handbook of Research on Improving the Natural and Ecological Conditions. IGI Global of Timely Knowledge. Hershey, Pennsylvania 17033-1240, USA. 2023.– p.51-74.  https://doi.org/10.4018/978-1-6684-8248-3.ch004