The use of geoinformation systems for planning and implementing the restoration of territorial communities
DOI:
https://doi.org/10.51798/sijis.v6i2.1008Keywords:
geoinformation systems, territorial communities, spatial planning, project management, spatial analysis, reconstruction, digital technologies, securityAbstract
Introduction: The relevance of the use of geodata systems is increasing in view of large-scale destruction of infrastructure caused by cataclysms, as well as human economic and political activity. The aim of the article is to analyse the potential applications of geoinformation systems (GIS) to optimize infrastructure restoration processes and reduce costs. Methodology: The research methodology is based on the analysis of the impact of GIS through statistical analysis, modelling and the use of weighted calculations. Results: The results of the study demonstrate that the implementation of GIS significantly reduces the time and costs of restoration, improve the accuracy of planning and reduce the risks of future destruction. Conclusions: The article identifies the key challenges associated with the implementation of these systems, including technical limitations, the need for qualified specialists and ensuring data security. Proposed solutions include the development of national standards, the training of specialists, and expanding the use of modern technologies. The practical significance of the work is carrying out calculations on the effective implementation of GIS for the restoration of territorial communities in Ukraine in the post-war period. Further research should focus on studying the impact of innovative technologies on reconstruction processes and their integration into national recovery projects.
References
Alazzam, F. A. F., Shakhatreh, H. J. M., Gharaibeh, Z. I. Y., Didiuk, I., & Sylkin, O. (2023). Developing an information model for e-commerce platforms: A study on modern socioeconomic systems in the context of global digitalization and legal compliance. Ingenierie des Systemes d'Information, 28(4), 969-974. https://doi.org/10.18280/isi.280417
Ayodele, I. V., & Emmaogboji, E. G. (2024). Web-based geographic information system for location based healthcare service delivery within Akure Metropolis. American Journal of Environment Studies, 7(1), 15–42. https://doi.org/10.47672/ajes.1842
Bansal, V. K. (2023). A road-based 3D navigation system in GIS: A case study of an institute campus. International Journal of Applied Geospatial Research, 14(1), 1-20. https://doi.org/10.4018/IJAGR.316887
Batoon, J. A., & Piad, K. C. (2023). Optimizing vaccine access: A web-based scheduling system with geo-tagging integration and decision support for local health centers. Open Journal of Applied Sciences, 13(5), 720–730. https://doi.org/10.4236/ojapps.2023.135057
Calzati, S., & van Loenen, B. (2023). An ethics assessment list for geoinformation ecosystems: Revisiting the integrated geospatial information framework of the United Nations. International Journal of Digital Earth, 16(1), 1418–1438. https://doi.org/10.1080/17538947.2023.2200041
Chunin, S. A., Shanygin, S. I., Kuzmin, V. A., Orekhov, D. A., Gulyukin, A. M., Botalova, D. P., & Yeshchenko, I. D. (2023). A model of a geoinformation system to support decision-making about the epizootic situation in a municipality. Legal Regulation in Veterinary Medicine, 4, 54–59. https://doi.org/10.52419/issn2782-6252.2022.4.54
Deuerlein, J. W., Bernard, T., Gonuguntla, N. M., Thomas, J., Canzler, A., Keifenheim, H., & Parra, S. (2022, July 18-22). W-NET4.0 – Integrated platform for small and medium sized water supply utilities [Conference presentation]. 2nd International Join Conference on Water Distribution System Analysis (WDSA) & Computing and Control in the Water Industry (CCWI), Valencia, Spain. https://doi.org/10.4995/wdsa-ccwi2022.2022.14095
Dudar, T. V., Saienko, T. V., Radomska, M. M., Lubsky, M. S., Yavniuk, A. A., Rozhko, V. V., & Hay, A. Ye. (2024). Innovation and digitalization in environmental education: The case study of climate change adaptation and analysis of land surface temperature. Journal of Geology, Geography and Geoecology, 32(4), 724–733. https://doi.org/10.15421/112363
Freymueller, J., Schmid, H. L., Senkler, B., Lopez Lumbi, S., Zerbe, S., Hornberg, C., & McCall, T. (2024). Current methodologies of greenspace exposure and mental health research — A scoping review. Frontiers in Public Health, 12, 1360134. https://doi.org/10.3389/fpubh.2024.1360134
Gardener, M. (2017). Statistics for ecologists using R and Excel: data collection, exploration, analysis and presentation. Pelagic Publishing Ltd.
Gnädinger, J. (2023). Standardization of landscape and environmental planning for 3D/4D BIM and LIM projects. Journal of Digital Landscape Architecture, 8, 160–166. https://doi.org/10.14627/537740017
Goihl, S. (2023). Mapping overwintering grain stubbles using machine-learning methods and image compositions for common agriculture policy-control and water framework directive connected activities. Journal of Applied Remote Sensing, 17(1), 1-17. https://doi.org/10.1117/1.jrs.17.014515
Gould-Davies, N. (2024). Ukraine: The balance of resources and the balance of resolve. Survival, 66(2), 55-62. https://doi.org/10.1080/00396338.2024.2332057
Gryshchenko, I., Yermak, O., Ovcharenko, R., Prodan, T., & Hadzhiieva, A. B. (2024). Public control and crime prevention: Interaction at the state and regional levels. Pakistan Journal of Criminology, 16(3), 763-778. https://doi.org/10.62271/pjc.16.3.763.778
Hagmann, D., Ankerl, B., Greisinger, M., Miglbauer, R., & Kirchengast, S. (2023). Where are the Roman women of Ovilava? A spatio-temporal approach to interpret the female deficit at the eastern Roman cemetery (Gräberfeld Ost) of Ovilava, Austria. Anthropological Review, 86(2), 89–118. https://doi.org/10.18778/1898-6773.86.2.08
Hoang, V. T., Kuzin, A. A., Zobov, A. E., & Zobovа, A. A. (2023). Features of the system of epidemiological surveillance of infectious diseases in the Socialist Republic of Vietnam. Journal Infektology, 15(1), 108–114. https://doi.org/10.22625/2072-6732-2023-15-1-108-114
Hunko, I. S. (2023). Experience of using geoinformation system Google Earth for digital situation modelling. Scientific Notes of Taurida National V.I. Vernadsky University. Series: Technical Sciences, 6, 312–316. https://doi.org/10.32782/2663-5941/2023.6/47
Jakimow, B., Janz, A., Thiel, F., Okujeni, A., Hostert, P., & van der Linden, S. (2023). EnMAP-Box: Imaging spectroscopy in QGIS. SoftwareX, 23, 101507. https://doi.org/10.1016/j.softx.2023.101507
Karelkhan, N., Kadirbek, A., & Schmidt, P. (2023). Setting up and implementing ArcGIS to work with maps and geospatial data with python for teaching geoinformation systems in higher education. International Journal of Emerging Technologies in Learning, 18(14), 271–281. https://doi.org/10.3991/ijet.v18i14.39833
Karpinskyi, Y., Lazorenko, N., Kin, D., Maksymova, Y., Nesterenko, O., Zhao, H., & Borowczyk, J. (2024). Geoinformation support of the decision-making support system for the reconstruction of cultural heritage objects. International Journal of Conservation Science, 15, 119–128. https://doi.org/10.36868/IJCS.2024.SI.10
Keller, C. A., Knowland, K. E., Duncan, B. N., Liu, J., Anderson, D. C., Das, S., & Pawson, S. (2021). Description of the NASA GEOS composition forecast modelling system GEOS-CF v1.0. Journal of Advances in Modelling Earth Systems, 13(4), 2020MS002413. https://doi.org/10.1029/2020MS002413
Kiseleva, S. V., Lisitskaya, N. V., Popel’, O. S., Rafikova, Y. Y., Tarasenko, A. B., Frid, S. E., & Shakun, V. P. (2023). Geoinformation systems for renewable energy (review). Thermal Engineering, 70(11), 939–949. https://doi.org/10.1134/S0040601523110071
Kraemer, H. C., & Blasey, C. (2015). How many subjects?: Statistical power analysis in research. Sage publications.
Kryshtanovych, M., Akimova, L., Shamrayeva, V., Karpa, M., Akimov, O. (2022). Problems of European integration in the construction of EU security policy in the context of counter-terrorism. International Journal of Safety and Security Engineering, 12(4), 501-506. https://doi.org/10.18280/ijsse.120411
KSE (2024). Report on direct damage to infrastructure from destruction as a result of Russia’s military aggression against Ukraine as of the beginning of 2024. Kyiv School of Economics. https://kse.ua/wp-content/uploads/2024/04/01.01.24_Damages_Report.pdf (Last accessed date: 19 December 2024).
Kunchev, I., & Angelova, M. (2023). Development of a conceptual model of a road accident geoinformation system. Kartografija i Geoinformacije, 22(39), 4–19. https://doi.org/10.32909/kg.22.39.1
de Lange, N. (2023). Geoinformation systems. In: Geoinformatics in Theory and Practice, Springer Textbooks in Earth Sciences, Geography and Environment (pp. 375–433). Berlin, Heidelberg: Springer. https://doi.org/10.1007/978-3-662-65758-4_9
Naß, A., & van Gasselt, S. (2023). A cartographic perspective on the planetary geologic mapping investigation of Ceres. Remote Sensing, 15(17), 4209. https://doi.org/10.3390/rs15174209
Racetin, I., Ostojić Škomrlj, N., Peko, M., & Zrinjski, M. (2023). Fuzzy multi-criteria decision for geoinformation system-based offshore wind farm positioning in Croatia. Energies, 16(13), 4886. https://doi.org/10.3390/en16134886
Rădulescu, A. T., Rădulescu, C. M., Kablak, N., Reity, O. K., & Rădulescu, G. M. T. (2023). Impact of factors that predict adoption of geomonitoring systems for landslide management. Land, 12(4), 752. https://doi.org/10.3390/land12040752
Shithil, S. M., & Adnan, M. A. (2023). A prediction based replica selection strategy for reducing tail latency in geo-distributed systems. IEEE Transactions on Cloud Computing, 11(3), 2954–2965. https://doi.org/10.1109/TCC.2023.3244203
da Silva Peres, L. D., Sluter, C. R., & Velho, L. F. (2023). User-centered design of a geoinformation system for identifying the visitor’s impact in environmentally fragile areas in natural parks. Abstracts of the ICA, 6, 1–2. https://doi.org/10.5194/ica-abs-6-196-2023
Stupen, R., Ryzhok, Z., Stupen, N., & Stupen, O. (2023, October 19-21). Methodology for creating geoportals of local self-government bodies using geoinformation systems [Conference presentation]. International Scientific and Technical Conference on Computer Sciences and Information Technologies, Lviv, Ukraine. https://doi.org/10.1109/CSIT61576.2023.10324151
Theilen-Willige, B. (2023). Detection of ring structures and their surrounding tectonic pattern in South-Algeria, North-Mali and North-Niger based on satellite data. Energy and Earth Science, 6(2), 1-29. https://doi.org/10.22158/ees.v6n2p1
Vu, M. Q., Le, H. D., Pham, T. V., & Pham, A. T. (2023). Design of satellite-based FSO/QKD systems using GEO/LEOs for multiple wireless users. IEEE Photonics Journal, 15(4), 1-15. https://doi.org/10.1109/JPHOT.2023.3294723
Xu, L., Fan, C., Luo, M., Li, S., Han, J., Fu, X., & Xiao, B. (2023). Elimination mechanism of coal and gas outburst based on geo-dynamic system with stress–damage–seepage interactions. International Journal of Coal Science and Technology, 10(74), 1-15. https://doi.org/10.1007/s40789-023-00651-z
Zhunissov, N. (2023). The possibilities of using geoinformation systems in the educational process. Q A Iasaýı Atyndaǵy Halyqaralyq Qazaq-Túrіk Ýnıversıtetіnіń Habarlary (Fızıka Matematıka Informatıka Serııasy), 24(1), 95–105. https://doi.org/10.47526/2023-1/2524-0080.09
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2025 Iryna Gryshchenko, Dmytro Gulevets , Nataliia Prokopenko , Oleksii Dniprov, Volodymyr Stadnikov
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
