Conceptual model of cartographic monitoring field geophysical surveys and proposals for its implementation

Cartography
UDC: 
528.94
DOI: 
10.22389/0016-7126-2022-984-6-30-41
1 Loginov D.S.
Year: 
2022
№: 
6
984
Pages: 
30-41

Target Horizon, LLC

1, 
Abstract:
Timely performance of field geophysical surveys directly affects the deadline of identification and preparation for exploitation of new mineral deposits. Current monitoring the productivity of geophysical crews making field surveys is based on daily preparation and analysis of reporting tabular and cartographic materials, the formation of which requires skills in working with geodata. To optimize fieldwork production, you need an intuitive interface that provides unified access to information for a large number of users and does not require installation and training specialized software. The author offers a conceptual model of field geophysical survey cartographic monitoring and measures for adapting web-mapping technology to the specifics of field work regardless to the method of geophysical research used. The practical implementation of the conceptual model will solve the tasks of automated preparing daily reports, storing information in a common database and formation of interactive cartographic images. As a result, developing a web-mapping service is expected, its use will contribute to the adoption of operational management decisions to prevent violating the terms of contractors’ obligations for performing field geophysical research in the framework of geological exploration works.
The author is grateful to Ph. D. S. A. Krylov and to the reviewers for their constructive and valuable comments, which allowed to improve the quality of article content.
References: 
1.   Abdullin R. K., Berezina O. A., Maksimovich N. G. Sozdanie bazy geodannykh dlya otsenki sostoyaniya okruzhayushchei sredy likvidirovannogo Kizelovskogo ugol'nogo basseina. Izv. Tul'skogo gos. un-ta. Nauki o Zemle, 2021, 3. pp. 39–54.
2.   Anikaeva A. A. Vozmozhnosti i perspektivy ispol'zovaniya Collector for ArcGIS v neftegazovoi otrasli. Problemy razrabotki mestorozhdenii uglevodorodnykh i rudnykh poleznykh iskopaemykh, 2019, no. 1, pp. 257–259.
3.   Beloshitskii A. V., Bulankin A. A., Garaishin Sh. G. Programmnoe obespechenie dlya sostavleniya abrisa pri provedenii seismorazvedochnykh rabot. Geofizika, no. 1. – 2021, pp. 71–77.
4.   Gafarov R. M., Siraev I. A., Denisenko N. V., Yagudin I. R., Idiyatov R. Kh. Sistema kontrolya kachestva polevykh seismorazvedochnykh rabot. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdenii, 2021, no. 6 (354), pp. 34–41. DOI: 10.33285/2413-5011-2021-6(354)-34-41.
5.   Gura D. A., Shevchenko G. G., Polennikov Yu. P., Amarina E. D. Topografo-geodezicheskoe i navigatsionnoe obespechenie geologorazvedochnykh rabot. Science of Europe, 2017, no. 12-1 (12), pp. 78–87.
6.   Kargashina M. A., Oboev V. S., Mikheeva A. I. Vnedrenie geoportal'nykh tekhnologii v praktiku ekologicheskikh issledovanii territorii dobychi i transportirovki uglevodorodov. Natsional'naya kartograficheskaya konferentsiya-2018: Sb. tezisov, Moskva: Geograficheskii fakul'tet MGU im. M. V. Lomonosova, 2018, pp. 114–115.
7.   Karpachevskii A. M., Titov G. S. Proektirovanie bazy prostranstvenno-vremennykh dannykh o magistral'nykh elektricheskikh setyakh Rossii. InterKarto. InterGIS, 2021, Vol. 27, no. 2, pp. 306–314. DOI: 10.35595/2414-9179-2021-2-27-306-314.
8.   Katsko S. Yu. Klassifikatsiya i printsipy raboty geoinformatsionnykh web-serverov v internet-sisteme «klient – server». Geo-Sibir', 2006, Vol. 1, no. 1, pp. 211–215.
9.   Loginov D. S. Opyt ispol'zovaniya geodannykh v kartograficheskom obespechenii geologorazvedochnykh rabot. Izvestia vuzov. Geodesy and Aerophotosurveying, 2021, Vol. 65, no. 5, pp. 598–608. DOI: 10.30533/0536-101X-2021-65-5-598-608.
10.   Taksior O. P., Polikarpov M. P. Tsifrovizatsiya inspektsionnoi deyatel'nosti: peredovye tekhnologii dlya kompetentnykh spetsialistov. PRONEFT'. Professional'no o nefti, 2021, no. 2 (20), pp. 81–90. DOI: 10.51890/2587-7399-2021-6-2-81-90.
11.   Chervyakov R. V., Perlov D. K., Konnov A. G. Ispol'zovanie tekhnologii geologicheskoi dokumentatsii Sherpa na mobil'nykh ustroistvakh pri provedenii polevykh rabot. Struktura, veshchestvo, istoriya litosfery Timano-Severoural'skogo segmenta: Sb. tr. 28-i nauch. konf, Syktyvkar: In-t geologii Komi NTs UrO RAN, 2019, pp. 188–191.
12.   Bandrova T., Pashova L. (2020) A conceptual framework for using geospatial big data for web mapping. Proceedings 8th International Conference on Cartography and GIS, no. 1, pp. 521–534.
13.   Dinkov D., Bonchev S. (2020) 3D historical reconstruction with interactive web-based application. Proceedings 8th International Conference on Cartography and GIS, no. 1, pp. 656–667.
14.   Duarte L., Teodoro A.C., Lobo M., Viana J., Pinheiro V., Freitas A. (2021) An Open Source GIS Application for Spatial Assessment of Health Care Quality Indicators. ISPRS International Journal of Geo-Information, no. 10 (4): 264, DOI: 10.3390/ijgi10040264.
15.   Nistor-Lopatenco L., Iacovlev A. (2020) WEB GIS solution for urban planning documentation workflow. E3S Web of Conferences. EEPG Tech 2019, 5 p. DOI: 10.1051/e3sconf/202017102005.
16.   Rocca F. (2018) Remote sensing from space for oil prospecting. Conference Proceedings, DOI: 10.3997/2214-4609.201801894.
17.   Wieser D., Kriz K. (2021) Climate and Vine – Representation and communication of spatio-temporal relationships in the web application AustrianVineyards.com. Proceedings of the international cartographic association, no. 4: 1–5, DOI: 10.5194/ica-proc-4-113-2021.
18.   Yuanchen Li, Bingjie Wei, Xin Wang (2017) A Web-Based Visual and Analytical Geographical Information System for Oil and Gas Data. ISPRS International Journal of Geo-Information, no. 6 (3), DOI: 10.3390/ijgi6030076.
Citation:
Loginov D.S., 
(2022) Conceptual model of cartographic monitoring field geophysical surveys and proposals for its implementation. Geodesy and cartography = Geodezia i Kartografia, 83(6), pp. 30-41. (In Russian). DOI: 10.22389/0016-7126-2022-984-6-30-41
Publication History
Received: 10.01.2022
Accepted: 07.06.2022
Published: 20.07.2022

Content

2022 June DOI:
10.22389/0016-7126-2022-984-6