Conceptual foundation for spatial data display in the mineral resource sector

Cartography
UDC: 
528.9
DOI: 
10.22389/0016-7126-2024-1010-8-2-13
1 Kopylova N.S.
2 Demidova P.M.
3 Kolesnik O.A.
4 Sannikova A.P.
5 Sasonova S.G.
Year: 
2024
№: 
8
1010
Pages: 
2-13

Empress Catherine II Saint Petersburg Mining University

1, 
2, 
3, 
4, 

Transport Design Solutions

5, 
Abstract:
The authors consider spatial data as the basis for information provision of the territory. It is noted that at displaying it, significant is to choose the coordinate system and cartographic projection most suitable for a particular territory or object. The issues related to the accuracy of the mentioned information representation play a crucial role. In popular cartographic services and web applications for data display, the accuracy of the results is low; they cannot be correctly applied to engineering tasks. The majority of GIS products incorporate numerous built-in coordinate systems, allowing selection of a suitable projection for a specific task. It is established that today in the Russian Federation there is a number of issues concerned to coordination and displaying objects related to the mineral resource complex, as well as their presentation in the Unified State Real Estate Register. Various districts use different systems; this necessitates transforming coordinates, leading to accumulating errors. Additionally, the multi-stage principles involved in conversion and data display contribute to reduced accuracy. In the case of solving overview visualization tasks, this may not cause serious problems for the user; however, the design of information on objects of the mineral resource complex requires compliance with the desired graphical accuracy. Therefore, developing the coordination principle is closely connected with application of modern methods for data acquisition, digital representation, display, and storage using various information systems, which is directly determined by the strategic tasks of topographic, geodetic, and cartographic support in the Russian Federation until 2030
References: 
1.   Valkov V.A., Vinogradov K.P., Valkova E.O., Mustafin M.G. (2022) Creating highly informative rasters based on laser scanning and aerial photography data. Geodezia i Kartografia, 83(11), pp. 40-49. (In Russian). DOI: 10.22389/0016-7126-2022-989-11-40-49.
2.   Vinogradov A. V., Mazurov B. T. Perspektivy ispol’zovanija special’nyh geodezicheskih proekcij i mestnyh sistem koordinat. Vestnik SGUGiT, 2017, Vol. 22, no. 1, pp. 18–29.
3.   Graur A. V. Matematicheskaya kartografiya: uchebnik. Leningrad: Uchpedizd. Leningradskoe otdelenie, 1938, 312 p.
4.   Zagrebin G. I., Krylov S. A., Kotova O. I. Sozdanie interaktivnykh web-kart na territoriyu goroda. Interekspo Geo-Sibir', 2021, Vol. 1, pp. 169–177.
5.   Karpik A. P., Lisitskii D. V. Perspektivy razvitiya geodezicheskogo i kartograficheskogo proizvodstva i novaya paradigma geoprostranstvennoi deyatel'nosti. Vestnik SSUGT, 2020, Vol. 2, pp. 19–29. DOI: 10.33764/2411-1759-2020-25-2-19-29.
6.   Karpik A.P., Obidenko V.I., Pobedinskiy G.G. (2021) Research of the need of the federal executive authorities of the Russian Federation for spatial data. Geodezia i Kartografia, 82(2), pp. 49-63. (In Russian). DOI: 10.22389/0016-7126-2021-968-2-49-63.
7.   Kopylova N.S., Starikov I.P. (2021) Methods of displaying geospatial information using cartographic web technologies for the Arctic region and the continental shelf. Geodezia i Kartografia, 82(5), pp. 15-22. (In Russian). DOI: 10.22389/0016-7126-2021-971-5-15-22.
8.   Kopylova N.S., Uvarova Sofia Genadyevna (2022) Optimizing calculation, arrangement and storage of information on the mathematical basis of topographic maps for high-latitude areas. Geodezia i Kartografia, 83(11), pp. 32-39. (In Russian). DOI: 10.22389/0016-7126-2022-989-11-32-39.
9.   Litvinenko V. S., Petrov E. I., Vasilevskaya D. V., Yakovenko A. V., Naumov I. A., Ratnikov M. A. Otsenka roli gosudarstva v upravlenii mineral'nymi resursami. Zapiski Gornogo instituta, 2023, Vol. 259, no. 1, pp. 95–111. DOI: 10.31897/PMI.2022.100.
10.   Mustafin M. G., Kologrivko A. A., Vasil'ev B. Yu. Analiz tochnosti postroeniya tsifrovykh modelei rel'efa na osnove dannykh periodicheskogo vozdushnogo lazernogo skanirovaniya gornopromyshlennogo ob"ekta. Gornyi zhurnal, 2023, no. 2, pp. 49–69. DOI: 10.17580/gzh.2023.02.09.
11.   Nyrtsov M. V. Problemy matematicheskoi kartografii v GIS. InterKarto. InterGIS, 2019, Vol. 25, no. 1, pp. 332–336. DOI: 10.35595/2414-9179-2019-1-25-332-336.
12.   Obidenko V. I., Gorobtsov S. R. Preobrazovaniya prostranstvennykh dannykh v gosudarstvennuyu geodezicheskuyu sistemu koordinat 2011 goda v PO GIS. Vestnik SSUGT, 2021, Vol. 26, no. 5, pp. 27–39.
13.   Ponomarenko M. R., Kutepov Yu. I., Shabarov A. N. Informatsionno-analiticheskoe obespechenie monitoringa sostoyaniya ob"ektov otkrytykh gornykh rabot na baze tekhnologii veb-kartografii. Gornyi informatsionno-analiticheskii byulleten' (nauchno-tekhnicheskii zhurnal), 2022, no. 8, pp. 56–70. DOI: 10.25018/0236_1493_2022_8_0_56.
14.   Sidorov D. V., Ponomarenko T. V. Primenenie tsifrovykh geomekhanicheskikh dvoinikov dlya prognozirovaniya i otsenki riskov poteri zapasov v proektakh razrabotki rudnykh mestorozhdenii. Gornaya promyshlennost', 2022, no. 3, pp. 112–117. DOI: 10.30686/1609-9192-2022-3-112-117.
15.   Solov’ev M.D. Kartograficheskie proektsii. ОНТИ НКТП СССР:M. – L., 1937, pp. 128–129.
16.   Shevin A. V. Proekt tipovoi metodiki sozdaniya regional'nogo geoportala. Vestnik SGUGiT, 2019, no. 4, pp. 176–187.
17.   Kiselev V. A., Guseva N. V. (2022) Zoning pipeline routes according to the degree of danger of accidents using geoinformation systems and artificial neural networks. Mining informational and analytical bulletin (Scientific and technical journal), no. 10-2, pp. 185–192. DOI: 10.25018/0236_1493_2022_102_0_185.
Citation:
Kopylova N.S., 
Demidova P.M., 
Kolesnik O.A., 
Sannikova A.P., 
Sasonova S.G., 
(2024) Conceptual foundation for spatial data display in the mineral resource sector. Geodesy and cartography = Geodezia i Kartografia, 85(8), pp. 2-13. (In Russian). DOI: 10.22389/0016-7126-2024-1010-8-2-13
Publication History
Received: 29.12.2023
Accepted: 29.08.2024
Published: 20.09.2024

Content

2024 August DOI:
10.22389/0016-7126-2024-1010-8