Hybrid algorithms for geospatial analysis of dam location points in protective tasks for protected areas

Objective. In recent decades, criteria for identifying potential areas have evolved hand in hand with technological tools such as geographic information systems (GIS). However, the criteria for the preservation of protected areas are often not taken into account, thus causing damage to environmental biodiversity that can become irreparable. This paper presents the way of optimizing the process of locating key terrain points by developing a hybrid algorithm for geospatial analysis in QGIS. The goal is to speed up computational time, which is a critical variable for the entire key point detection process, and to suggest potential areas that do not pose a threat to biodiversity.
Methods. The strategy used is based on two fundamental assumptions: identifying the tops of spatial objects (rivers) and analyzing the distances between spatial objects (rivers and adjacent territories). The tops extraction allows obtaining potential points, while the distance analysis allows selecting among them those points that are in the range acceptable for locating a dam, provided that the least possible damage to the biodiversity of the adjacent territory is caused. The algorithm was validated using the example of the hydrological network of Manicaragua, Cuba.
Results. The results were compared in terms of the calculation time used, the number of valid tops extracted, and the percentage reduction in the total number of areas. This comparison was made using one, two and three vector layers (.shp) with spatial objects representing strategic protected areas.
Conclusion. The results obtained show that the more representative the space data (.shp) used, the more effective the results obtained using the algorithm are in relation to environmental protection tasks. A reduction of up to 13% from originally detected key points has been achieved.

1. Pokhrel Y. et. al. A Review of the Integrated Effects of Changing Climate, Land Use, and Dams on Mekong River Hydrology // Water. Multidisciplinary Digital Publishing Institute, 2018. V. 10, № 3. P. 266. DOI:10.3390/w10030266.

2. Vsemirnyy fond dikoy prirody (WWF). Plotiny i razvitiye: novaya metodicheskaya osnova dlya prinyatiya resheniy // Otchet vsemirnoy komissii po plotinam. Moskva, 2009. 200 s. [World Wildlife Fund (WWF). Dams and development: A new framework for decision-making // Overview of the report by the World Commission on Dams. Moscow, 2009. P. 200. (In Russ)]

3. Abdrazakov F., Pankova T., Orlova S. Prognozirovaniye veroyatnosti i vozmozhnykh posledstviy avariy na plotine // Vestnik BGTU im. V.G. Shukhova. 2019. T. 4, № 1. S. 65–72 DOI:10.12737/article_5c50620ee70624.66669200. [Abdrazakov F., Pankova T., Orlova S. Prediction of probability and consequences of accidents on the dam // Bulletin of Belgorod State Technological University named after. V. G. Shukhov. 2019. Vol. 4, No. 1. P. 65–72. DOI:10.12737/article_5c50620ee70624.66669200. (In Russ)]

4. Azimi Sardari M.R. et. al. Modeling the Impact of Climate Change and Land Use Change Scenarios on Soil Erosion at the Minab Dam Watershed // Sustainability. Multidisciplinary Digital Publishing Institute, 2019. V. 11, № 12. P. 3353. DOI:10.3390/su11123353.

5. QGIS project. QGIS Documentation v: 3.4 [El. resource] / Vector general: Merge vector layers. 2020. URL: https://docs.qgis.org/3.4/en/docs/user_manual/processing_algs/qgis/vectorgeneral.html?highlight=merge#mergevector-layers.

6. Baghdadi N., Mallet C., Zribi M. QGIS and generic tools. 1st ed. / ed. Wiley. 2018. V. 1. P. 296. DOI:10.1002/9781119457091.

7. Kim Y.-K. A Study on Urban Land Cover Classification Using Object-based Image Analysis (OBIA) Techniques // J. Korean Cadastre Inf. Assoc. The Korean Cadastre Information Association, 2020. V. 22, № 1. P. 122–144. DOI:10.46416/JKCIA.2020.04.22.1.122.

8. QGIS project. QGIS Documentation v:3.4 [Electronic resource] // Vector geometry: Extract vertices. 2020. URL: https://docs.qgis.org/testing/en/docs/user_manual/processing_algs/qgis/vectorgeometry.html#id180.

9. Vazquez S.R., Mokrova N. V. Comparison of Applicability of Different Computational Geometry Algorithms for the Detection of Vertices in River Layers in GIS Systems // 2020 International Multi-Conference on Industrial Engineering and Modern Technologies (FarEastCon). IEEE, 2020. P. 1–4. DOI:10.1109/FarEastCon50210.2020.9271660.

10. Vázquez S.R., Mоkrova N. V. Vector-spatial analysis of gis application layers for placing strategic points in dam design // Construction and industrial safety. 2021. № 20(72). P. 43–51. DOI:10.37279/2413-1873-2021-20-43-51.

11. ESRI. ArcGIS Pro [Electronic resource] // How proximity tools calculate distance. 2020. URL: https://pro.arcgis.com/ru/pro-app/tool-reference/analysis/how-near-analysis-works.htm.

12. Bojarska K. et. al. Winter severity and anthropogenic factors affect spatial behaviour of red deer in the Carpathians // Mammal Res. Springer, 2020. V. 65, № 4. P. 815–823. DOI:10.1007/s13364-020-00520-z.

13. Hysa A. Classifying the Forest Surfaces in Metropolitan Areas by Their Wildfire Ignition Probability and Spreading Capacity in Support of Forest Fire Risk Reduction // Integrated Research on Disaster Risks. Springer, Cham, 2021. P. 51–70. DOI:10.1007/978-3-030-55563-4_4.

14. Cuban Environment Agency (AMA). Integrating management of watersheds and coastal area in caribbean small island developing states. Ciudad de la Habana, 2001. 40 p.