Share:


The conceptual model of the structure and functional purpose of the geoinformation system for administrative and economic management of a regional airport

    Dmitry Prusov   Affiliation
    ; Olena Boyko Affiliation

Abstract

This article is devoted to the development of a conceptual model of the structure of the geoinformation system (GIS) for the administrative and economic management of regional airports, taking into account the requirements of world and national experience, international and national standards, modern technologies of geospatial data collection. The research is aimed at structuring all the facilities and objects of the airport complex and isolating components by location and function; development of a generalized scheme of directions for the use of administrative and business GIS at airports based on the analysis of world and domestic experience; establishing the need to use international and national standards of the “Geographic Information / Geomatics” series when creating an airport GIS; development of a generic scheme of the composition of the database of the Digital Single Topographic Base of the Airport, basic and profile geoinformation resources for the administrative and economic GIS; development of conceptual model of structure and functional purpose of GIS of administrative and economic management of the airport. The developed conceptual model reflects the main production processes and needs of airports, based on the database of the Digital Numeral Topographic Framework, is a complete and consistent model of the relationship between the administrative and economic needs of airports and the functionality of modern geoinformation systems for the efficient operation of objects, structures and facilities communications, analysis of the current state, monitoring and management decision-making.

Keyword : geospatial data, geoinformation system (GIS), administrative and economic management, regional airport, basic and profile datasets, attribute data

How to Cite
Prusov, D., & Boyko, O. (2022). The conceptual model of the structure and functional purpose of the geoinformation system for administrative and economic management of a regional airport. Geodesy and Cartography, 48(2), 46–55. https://doi.org/10.3846/gac.2022.12570
Published in Issue
May 25, 2022
Abstract Views
395
PDF Downloads
388
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Andrews, C. (2019). Myths and Realities of BIM-GIS Integration – Resources for geoengineering users.

Boyko, O. (2018). Geoinformation Systems of ArcGis Airport Complexes. Urban Planning and Territorial Planning: Scientific Technical Proceedings, 68, 656–665 (in Ukrainian).

Boyko, O., Lyashenko, D., & Gorb, O. (2019). Development of a Conceptual Model for the Collection of Geospatial Data of Airports by Laser Scanning Methods for GIS Creation. Urban planning and territorial planning: Scientific and Technical Collection, 71, 60–71 (in Ukrainian). https://doi.org/10.32347/2076-815x.2019.71.60-71

Boyko, O., Lyashenko, D., & Prusov, D. (2019). Conceptual fundamentals of airport ВIM /GIS spatial data integration received by laser scan. Technical Sciences and Technologies, 4(18), 238–246 (in Ukrainian). https://doi.org/10.25140/2411-5363-2019-4(18)-238-246

Cabinet of Ministers of Ukraine. (2016). Resolution of the Cabinet of Ministers of Ukraine No. 126 “State target program for airport development for the period up to 2023” (in Ukrainian). https://zakon.rada.gov.ua/laws/show/126-2016-%D0%BF

Chen, W., Yuan, J., & Li, M. (2012). Application of GIS/GPS in Shanghai Airport Pavement Management System. Procedia Engineering, 29, 2322–2326. https://doi.org/10.1016/j.proeng.2012.01.308

Cherin, A. (2019). Ukrainian and international standards and specifications for the construction of modern GIS and geoportals (in Ukrainian). https://softpro.ua/ua/ukraiinski-ta-mijnarodni-standarti-i-specifikaciii-pobudovi-suchasnih-gis-ta-geoportaliv

Dasgupta, A. (2018). Integration of BIM and geospatial systems still a distant dream. Geospatial World. https://www.geospatialworld.net/article/integrat-ion-of-bim-and-geospatial-systems-still-a-distant-dream/

ЕСОММ Со. (2018). Proceedings of the XXI International Esri User Conference in Ukraine. http://ecomm.in.ua/main/114-vdbulasya-xxi-mzhnarodna-konferencya-koristuvachv-esri-v-ukrayin.html#sel=6:53,6:59

Esri and Perth Airport Website. (2016). Perth International Airport in Australia. Enterprise-wide access to location-based data and analytics. ArcReview, 1(76).

Esri. (2019). GIS as a strategic component of extensive moderni­zation at LAX. ArcReview, 2(89). https://arcreview.esri-cis.ru/2019/12/25/airport-gis/

Geoportal of the State Aviation Service of Ukraine. (2020). (in Ukrainian). https://avia.gov.ua

Gokhman, V. V., & Glebov, S. E. (2013). Airports around the World rely on the Power of GIS. ArcReview, 3(66) (in Russian).

Gruenfelder, T. (2006). Geoinformation technologies and cartographic databases in airport management. Bulletin of Geodesy and Cartography. Collection of scientific works, UDAGP, 4(43), 37–40 (in Ukrainian).

Hartsfield-Jackson Airport Representatives. (2016). World’s largest airport flies high with GIS. ArcReview, 1(76).

Huang, W., Raza, S. A., Mirzov, O., & Harrie, L. (2019). Assessment and benchmarking of spatially enabled RDF stores for the next generation of spatial data infrastructure. ISPRS International Journal of Geo-Information, 8(7), 310. https://doi.org/10.3390/ijgi8070310

International Civil Aviation Organization. (2019). Annex 14 to the Convention on International Civil Aviation, Vol. I. Design and operation of aerodromes. https://tdmegaprom.ru/uploads/images/ikao_prilozhenie-14_tom-1_aerodromy.pdf

Karpinsky, Yu., Lyashchenko, A., & Yasuyuki, O. (2016). Composition and principles of developing a national profile of standards for geographical information. Engineering Geodesy, 63, 110–121 (in Ukrainian). http://nbuv.gov.ua/UJRN/Ig_2016_63_13

Kuehne, D., & Andrews, C. (2016). Increasing interest in the fusion of GIS and BIM. Esri. ArcGIS Blog. https://www.esri.com/arcgis-blog/products/3d-gis/3d-gis/increasing-interest-in-the-fusion-of-gis-and-bim/

Lyashchenko, A., & Cherin, A. (2011). Architecture of modern GIS based on geospatial data base. Bulletin of Geodesy and Cartography, 5, 45–50 (in Ukrainian). http://nbuv.gov.ua/UJRN/vgtk_2011_5_11

Mitchell, A. (2000). GIS analysis guide. Part 1: Spatial models and relationships. ЕСОММ Со; Stylos.

National Standard of Ukraine. (2010). Complex of standards Topographic database “Rules for encoding and digitally describing vector data”, Vol. 2 (742-33739540 0012:2010) (in Ukrainian). http://gki.com.ua/ua/tehnichni-komitet-103

Palekha, Yu. (2013). Urban planning and GIS in Ukraine today: Some results of twenty years of cooperation. Arcreview, 2 (in Ukrainian). http://dipromisto.gov.ua/files/Publications/Palekha_stattya_gis_08.10.2014.pdf

Palekha, Yu., Oleshchenko, A., & Solomaha, I. (2012). Application of GIS technologies in town-planning projects at the state and regional levels. Scientific notes of the Vernadsky Taurida National University. Geography, 1, 155–166 (in Ukrainian).

Parrish, Ch., & Nowak, R. (2009). Improved Approach to LIDAR airport obstruction surveying using full-waveform data. Surveying Engineering, 135(2). https://doi.org/10.1061/(ASCE)0733-9453(2009)135:2(72)

Peters, J. (2018). Location intelligence saves Geneva airport millions. ArcReview, 3(86).

Prusov, D. (2009). Airports and their infrastructure: Investigation peculiarities of the aerodrome coverage interaction with soil basics with weak layers. Proceedings of the National Aviation University, 39(2), 129–133. https://doi.org/10.18372/2306-1472.39.1724

Prusov, D. (2012). Numerical research of the retaining constructions during reconstruction of the transport structures. Transport, 27(4), 357–363. https://doi.org/10.3846/16484142.2012.750623

Research Institute of Geodesy and Cartography. (n.d.). (in Ukrainian). http://gki.com.ua/ua/tehnichni-komitet-103

Stadnikov, V. (2016). Conceptual bases of development of regional automated system of urban cadastre of Odessa region. Modern Achievements of Geodetic Science and Production, І(31), 96–101 (in Ukrainian).

State Building Codes of Ukraine. (2019). Planning and development of territories (DBN B.2.2-12:2019) (in Ukrainian). http://dbn.co.ua/load/normativy/dbn/b_2_2_12/1-1-0-1802

Topographical-Geodetic and Cartographic Activity. Legislative and Regulatory Acts. Part 2. (2002). Vinnytsia: Anteks (in Ukrainian).

Verhovnaja Rada Ukrainy. (1998). Order of the Headquarters of Geodesy, Cartography and Cadastre at the Cabinet of Ministers of Ukraine No. 56 “Topographic Instruction in Scales 1:5000, 1:2000, 1:1000 and 1:500 (in Ukrainian). https://zakon.rada.gov.ua/laws/show/z0393-98?lang=ru

Vladimirov, Ie. (2016). The main decisions to create a geographic information system of the airport. Esri (in Russian). http://www.slideshare.net/IevgenVladimirov/esri-60108995