Вестник Пермского университета. Геология

В работе выполнен обзор нормативно-технической документации по применению глобальных навигационных спутниковых систем и геодезического мониторинга. Далее обоснован подбор допускаемой среднеквадратической погрешности и описана методика проведения измерений деформаций подземного трубопровода при помощи спутникового оборудования. Разработана программа проведения измерений деформаций объекта методами геометрического нивелирования и спутниковыми, рассчитаны приведенные затраты за период эксплуатации объекта обоих методов, выбран наиболее экономически эффективный способ. Отмечено преимущество применения спутниковых измерений по сравнению с оптическими геодезическими методами.

Gerko S.A., Markov S.S., Mazepa R.B. 2021. Perspektivy ispolzovaniya GLONASS pri reshenii spetsialnykh zadach [Prospects for using GLONASS in solving special problems]. Elektrosvyaz. 11:38-46. (in Russian) doi:10.34832/ELSV.2021.24.11.004.

Gilaev D.M. Zagretdinov A.A., Zagretdinov R.V. 2021. Opyt i perspektivy ispolzovaniya GNSS tekhnologiy na mestorozhdeniyakh nefti i gaza [Experience and prospects for using GNSS technologies in oil and gas fields]. Surveyor's Bulletin. 2(141):21-27. (in Russian)

Elizarov A.S., Kurchatova A.N. 2020. Monitoring nadzemnykh truboprovodov s pomoshchyu globalnykh navigatsionnykh sputnikovykh sistem [Overhead pipeline monitoring using global navigation satellite systems]. Bulletin of SGUGiT (Siberian State University of Geosystems and Technologies). 25(1):28-42.(in Russian) doi: 10.33764/2411-1759-2020-25-1-28-42.

Sokolova V.A., Morkovskaya S.A., Naumenko V.S., Kushtin V.I. 2019. Sozdanie vysotnogo geodezicheskogo obosnovaniya dlya nablyudeniya za osadkami sooruzheniy [Creation of high-altitude geodetic justification for monitoring the structures subsidence]. In: Transport: science, education, production (Transport-2019). V. 3. Technical sciences. Height. State Univ. communication routes. Rostov, pp. 176–179. (in Russian)

Nesterenko M.Yu., Tsvyak A.V. 2016. Otsenka vozmozhnosti i tochnosti primeneniya GNSS-sistem dlya monitoringa deformatsiy zemnoy poverkhnosti na razrabatyvaemykh mestorozhdeniyakh uglevodorodov [Assessing the feasibility and accuracy of using GNSS systems for monitoring earth surface deformations in developed hydrocarbon fields]. Bulletin of the Orenburg Scientific Center of the Ural Branch of the Russian Academy of Sciences. 4:15. (in Russian)

Nesterenko Yu.M. Tsvyak A.V., Nesterenko M.Yu. 2017. Metodicheskie osnovy geodinamicheskogo monitoringa s ispolzovaniem globalnykh navigatsionnykh sputnikovykh sistem [Methodological foundations of geodynamic monitoring using global navigation satellite systems]. Bulletin of the Orenburg Scientific Center of the Ural Branch of the Russian Academy of Sciences. 4:10. (in Russian)

Kushtin V.I., Revyakin A.A., Sokolova V.A., Dobrynin N.F. 2020. Sovremennye metody monitoringa deformatsiy zdaniy i sooruzheniy [Modern methods of monitoring of buildings and utilities deformation]. Engineering Bulletin of the Don. 11(71):27-37. (in Russian)

Fyalkovsky A.L. 2015. Deformatsionnyy monitoring vysotnykh sooruzheniy s ispolzovaniemglobalnykh navigatsionnykh sputnikovykh sistem [Deformation monitoring of high-rise structures using global navigation satellite systems]. Promyshlennoe i grazhdanskoe stroitelstvo. 5:54-59. (in Russian)

Yurov F.D. 2022. Osobennosti organizatsii monitoringa lineynykh transportnykh sistem v kriolitozone [Features of monitoring organization at linear transport systems in the permafrost zone]. In: Prospects for the development of engineering surveys in construction in the Russian Federation. Moscow, Geomarketing, pp. 234-242. (in Russian)