Methodology for creating a geoinformation-analytical system to monitor irrigated lands in the South-East of Kazakhstan

DOI: 10.35595/2414-9179-2020-3-26-286-293

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Об авторах

Ilan Shakibayev

RSU Zonal hydrogeological and Reclamation Center of the Ministry of Agriculture of the Republic of Kazakhstan,
Baishev str., 113, 050018, Almaty, Kazakhstan,
E-mail: ilan_2004@mail.ru

Dinara Barmakova

RSU Zonal hydrogeological and Reclamation Center of the Ministry of Agriculture of the Republic of Kazakhstan,
Baishev str., 113, 050018, Almaty, Kazakhstan,
E-mail: barmakova_dina@mail.ru

Zhaiyk Yerikuly

RSU Zonal hydrogeological and Reclamation Center of the Ministry of Agriculture of the Republic of Kazakhstan,
Baishev str., 113, 050018, Almaty, Kazakhstan,
E-mail: zerikuly@mail.ru

Gennadiy Rau

NCJSC Kazakh National Agrarian University,
Abay Ave, 8, 050010, Almaty, Kazakhstan,
E-mail: genadiyr@gmail.com

Zhanar Kadasheva

NCJSC Kazakh National Agrarian University,
Abay Ave, 8, 050010, Almaty, Kazakhstan,
E-mail: dikuwa_90@mail.ru

Ilkhom Begmatov

Tashkent Institute of Irrigation and Agricultural Mechanization Engineers,
Uzbekistan,
E-mail: ilkhommatbe@mail.ru

Аннотация

At present, the study of natural objects without modern information technologies is almost impossible. The use of GIS for monitoring spatial features of irrigation systems uncovers broad opportunities. The development of the organizational structure, the selection of the necessary software tools for the collection, storage, processing and analysis of semantic data integrated with spatial objects is an urgent task and has important scientific and practical value.

The irrigated lands located in the southeast of Kazakhstan within the Almaty region are the object of research. Monitoring of these land salinization is carried out, including hydrogeological and hydrological observations and soil reclamation studies.

The article discusses the methodology for creating a geographic information and analytical system to monitor irrigated lands, and describes its organizational structure. The content of the database, the composition of functional components, the basic properties and capabilities of laboratory processing and analyzes of field materials are described. The cartographic material component describes its basic properties, including properties intended for analysis of database objects and their spatial point analogues. Also, the possibilities for ArcGIS application modules to automate the process of constructing maps of the hydrogeological and reclamation conditions of irrigated objects, and the possibilities for automated calculation of areas in specified gradations of depth and groundwater salinity to assess the reclamation state of these lands are shown.

Ключ. слова

GIS, monitoring of irrigated land, database, groundwater level, salinization

Список литературы

  1. Gostishev D.P., Korsak V.V., Holudeneva O.Iu. Development of a geographic information system to support decision-making on land reclamation management. Problems of land reclamation and ways to solve them: collection of scientific papers GA Volga Research Institute of Hydraulic Engineering and Land Reclamation. Moscow: Meliovodinform, 2001. Part II. Р. 22–30 (in Russian).
  2. Gorokhova I.N., Filippov D.V. Application of geographic information technologies and satellite imagery materials for monitoring irrigated lands of the Svetloyars irrigation system. Exploration of Earth and Space, 2017. No 4. Р. 79–87 (in Russian).
  3. Panichkin V.Iu., Miroshnichenko O.L., Erıkuly J. Geoinformation technologies in hydrogeological mapping. Bulletin of the Academy of Sciences of the Republic of Kazakhstan — Almaty, 2014. No 5. Р. 76–81.
  4. Shakibaev I.I. Hydrogeological and meliorative aspects of the issues of irrigated lands in the south of Kazakhstan. 2014. 304 р. (in Russian).
  5. Zanosova V.I., Postnova I.S., Grebenkına D.M. GIS technology in conducting local monitoring of the hydrogeological-reclamation state of irrigated lands. Bulletin of the Altai State Agrarian University — Barnaul, 2015. No 7. Р. 57–63 (in Russian).
  6. Bouksila F., Bahri A., Berndtsson R., Persson M., Rozema J., Van der Zee S.E.A.T.M. Assessment of soil salinization risks under irrigation with brackish water in semiarid unisia. Environmental and Experimental Botany, 2013. V. 92. Р. 176–185. DOI: 10.1016/j.envexpbot.2012.06.002.
  7. Kumar A., Dubey O.P., Ghosh S.K. GIS based irrigation water management. IJRET: International Journal of Research in Engineering and Technology, 2014. V. 03. Special Iss. 14/Nov-2014/SMART. Р. 62–65.
  8. Knox J.W., Weatherfield E.K. The application of GIS to irrigation water resource management in England and Wales. The Geographical Journal. V. 165. No 1. Р. 90–98.
  9. Saxena P.R. Prasad NSP Integrated land and water resources conservation and management-development plan using remote sensing and GIS of Chevella sub-watershed, R.R. Distict, Andhra Pradesh, India. The international archives of the photogrammetry, Remote Sensing and Spatial Information Sciences. Beijing, 2008. No 8. V. 37. Р. 729–732.

Для цитирования: Shakibayev I., Barmakova D., Yerikuly Zh., Rau G., Kadasheva Zh., Begmatov I. Methodology for creating a geoinformation-analytical system to monitor irrigated lands in the South-East of Kazakhstan. ИнтерКарто. ИнтерГИС. Геоинформационное обеспечение устойчивого развития территорий: Материалы Междунар. конф. M: Издательство Московского университета, 2020. Т. 26. Ч. 3. С. 286–293 DOI: 10.35595/2414-9179-2020-3-26-286-293

For citation: Shakibayev I., Barmakova D., Yerikuly Zh., Rau G., Kadasheva Zh., Begmatov I. Methodology for creating a geoinformation-analytical system to monitor irrigated lands in the South-East of Kazakhstan. InterCarto. InterGIS. GI support of sustainable development of territories: Proceedings of the International conference. Moscow: Moscow University Press, 2020. V. 26. Part 3. P. 286–293. DOI: 10.35595/2414-9179-2020-3-26-286-293