Article

Integration of satellite monitoring for flood risks forecasting on the example of the Dnister’s Flood Surveying Site

Denys Zorin, Kateryna Sysak
Abstract

The relevance of the study lies in the development, improvement and practical implementation of a geoinformation approach to flood risk forecasting within the Dniester flood control area by integrating satellite monitoring, spatial analysis and interpolation methods. The study was aimed at creating an effective system for identifying potentially dangerous areas, analysing floodwater pollution and assessing the impact of climate change on hydrometeorological processes in order to increase environmental safety and ensure sustainable risk management at the level of territorial communities. Mapping of Quaternary deposits, geomorphological levels and landscape structure was carried out, and a forecast map of flooding of territories with water rising by 1, 3, 5 and 10-12 meters was constructed. The final result was a 3D map, which is presented as an interpolated surface, created using the inverse weighted distance method. The optimal intervals of the value and size of the cells were selected: the obtained result allows not only to analyse the risks of flooding, but also to draw up reports with visualisation of data stored in the form of graphic images. For the first time, a map of the ecological risk of flooding of the Dniester flood control site by catastrophic floods was created for the Dniester Valley and adjacent territories of Podillia and Prykarpattia. The study showed that the process of flooding of the Dniester Valley occurs sequentially: first, the low floodplain is flooded (water rise +1 m), then the middle (+3 m), high (+5 m) floodplains and, finally, the first suprafloodplain terrace (+10-12 m). Based on the identified patterns, a system for predicting the rise of water during floods was developed. In addition to forecasting, this system performs the function of notifying the population about catastrophic manifestations of water elements

Download article

Received 18.12.2024

Revised 15.04.2025

Accepted 02.06.2025

https://doi.org/10.63341/esbur/1.2025.76
Retrieved from Vol. 16, No. 1, 2025
Pages 76-88

Suggested citation

Zorin, D., & Sysak, K. (2025). Integration of satellite monitoring for flood risks forecasting on the example of the Dnister’s Flood Surveying Site. Ecological Safety and Balanced Use of Resources, 16(1), 76-88. https://doi.org/10.63341/esbur/1.2025.76

References

  1. Adamenko, O., Zorin, D., & Mosiuk, M. (2020). Environmental situation of Dniester Regional Landscape Park. Visnyk of V. N. Karazin Kharkiv National University. Series Geology. Geography. Ecology, 53, 227-238. doi: 10.26565/2410-7360-2020-53-17.
  2. Adamenko, O., Zorin, D., & Radlowska, K. (2022). Forecasting of disaster floods in Dniester valley. Environmental Safety and Natural Resources, 42(2), 112-120. doi: 10.32347/2411-4049.2022.2.112-120.
  3. Ali, S.A., Parvin, F., Pham, Q.B., Vojtek, M., Vojteková, J., Costache, R., Linh, N.T., Nguyen, H.Q., Ahmad, A., & Ghorbani, M.A. (2020). GIS-based comparative assessment of flood susceptibility mapping using hybrid multi-criteria decision-making approach, naïve Bayes tree, bivariate statistics and logistic regression: A case of Topľa basin, Slovakia. Ecological Indicators, 117, article number 106620. doi: 10.1016/j.ecolind.2020.106620.
  4. Balch, J., et al. (2020). Social-environmental extremes: Rethinking extraordinary events as outcomes of interacting biophysical and social systems. Earth’s Future, 8(7), article number e2019EF001319. doi: 10.1029/2019EF001319.
  5. Bilas, G., et al. (2022). Land suitability analysis as a tool for evaluating soil-improving cropping systems. Land, 11(12), article number 2200. doi: 10.3390/land11122200.
  6. Davybida, L., Worsa-Kozak, M., Górniak-Zimroz, J., & Michalak, A. (2021). Spatial and temporal trend analysis of meteorological, hydrological and hydrogeological data (by the example of the San River basin). In International conference of young professionals “GeoTerrace-2021” (pp. 1-5). Lviv: European Association of Geoscientists & Engineers. doi: 10.3997/2214-4609.20215K3039.
  7. Dzyba, A., & Kyriienko, V. (2024). Recovery of Velykyi Luh through ecological restoration of the Kakhovka Reservoir. Ukrainian Journal of Forest and Wood Science, 15(1), 25-40. doi: 10.31548/forest/1.2024.25.
  8. Halochkin, M.K. (2022). Theoretical principles and methods of hydrological modeling of flood zones using materials of remote sensing of the earth and geoinformation systems. (PhD dissertation, National University “Lviv Polytechnic”, Lviv, Ukraine).
  9. Hnatushenko, V.V., & Kashtan, V.Y. (2021). Automated pansharpening information technology of satellite images. Radio Electronics, Computer Science, Control, 2(57), 123-133. doi: 10.15588/1607-3274-2021-2-13.
  10. Kozlowski, T., Noran, O., & Trevathan, J. (2023). Designing an evaluation framework for IoT environmental monitoring systems. Procedia Computer Science, 219, 220-227. doi: 10.1016/j.procs.2023.01.284.
  11. Kuzmenko, E.D., Davybida, L.I., Bagriy, S.M., & Chepurnyi, I.V. (2019). Analysis and modeling of the hydrogeodynamic situation within the Stebnyk Deposit of potassium salts. Mineral Resources of Ukraine, 4, 30-37. doi: 10.31996/mru.2019.4.30-37.
  12. Lou, Y., Wang, P., Li, Y., Wang, L., Chen, C., Li, J., & Hu, T. (2023). Management of the designed risk level of urban drainage system in the future: Evidence from Haining city, China. Journal of Environmental Management, 351, article number 119846. doi: 10.1016/j.jenvman.2023.119846.
  13. Lysytsia, P., & Mudrak, O. (2022). Ecological monitoring of agricultural landscapes of Ralynivsk urban territorial community – the priority of their balanced useEcologically Balanced Development of Society: State, Problems, Prospects, 4, 146-154.
  14. Malkova, Y.O., et al. (2023). Isotope composition of groundwater and surface waters in the area of the Dombrovsky quarry of Kalush-Golinsk Deposit of potassium salts. Journal of Environmental Radioactivity, 257, article number 107083. doi: 10.1016/j.jenvrad.2022.107083.
  15. Mamo, S., Berhanu, B., & Melesse, A.M. (2019). Historical flood events and hydrological extremes in Ethiopia. In A.M. Melesse, W. Abtew & G. Senay (Eds.), Extreme hydrology and climate variability (pp. 379-384). Amsterdam: Elsevier. doi: 10.1016/B978-0-12-815998-9.00029-4.
  16. Moss, C., Lukac, M., Harris, F., Outhwaite, C.L., Scheelbeek, P.F.D., Green, R., Morales Berstein, F., & Dangour, A.D. (2020). The effects of crop diversity and crop type on biological diversity in agricultural landscapes: A systematic review protocol. Wellcome Open Research, 4, article number 101. doi: 10.12688/wellcomeopenres.15343.2.
  17. Myrontsov, M. (2020). Electrometry effective inverse problem solving method. Geoinformatics: Theoretical and Applied Aspectsdoi: 10.3997/2214-4609.2020geo090.
  18. Sosonna, N., Panasiuk, M., Malkova, Y., Kovalenko, I., Bagriy, S., & Buzynnyi, M. (2023). Mathematical model of hydrogeological conditions and forecasts of groundwater salinization under the influence of Dombrovsky Quarry of Kalush-Golinsky Potassium Salt Deposit. In 17th international conference monitoring of geological processes and ecological condition of the environment (pp. 1-5). Kyiv: European Association of Geoscientists & Engineers. doi: 10.3997/2214-4609.2023520185.
  19. Stetsenko, M.P. (Ed.). (1999). Conservation business in Ukraine on the threshold of millennia (current state, problems and development strategy). Kaniv: Ukrainian Phytosociological Centre.
  20. Sysak, K.O. (2024). The environmental audit of atmospheric air within the territory of Ivano-Frankivsk Region (under the example of Ivano-Frankivskcement corporation). In XII international scientific and practical conference “New problems of science and ways of their solution” (pp. 127-130). Paris: SC. Scientific Conferences. doi: 10.5281/zenodo.11454394.
  21. Trigub, V., & Domuschi, S. (2023). Ecotoxicological assessment of the influence of fuel stations on the pollution of urban soils with heavy metals. Odesa National University Herald. Geography and Geology, 28(1(42)), 68-83. doi: 10.18524/2303-9914.2023.1(42).282237.
  22. Wang, J., Zuo, R., & Liu, Q. (2024). Mapping geochemical anomalies by accounting for the uncertainty of mineralization-related elemental associations. Solid Earth, 15(6), 731-746. doi: 10.5194/se-15-731-2024.
  23. Zorin, D. (2022). Electronic cartographic GIS models of the environmental state of the Dniester Canyon. Environmental Safety and Natural Resources, 43(3), 110-118. doi: 10.32347/2411-4049.2022.3.110-118.