WebGIS technology and architectures
Main Article Content
Abstract
WebGIS allows everybody to reach geo-spatial data. It creates a rapid and advanced environment without place, time and the limitations of high processing power and high client computer. WebGIS, reshapes and makes use of all computer functions including gathering attribute data, storing, acquiring, analyzing and visualizing. WebGIS was employing the internet based maps and client-server architecture in order to provide these facilities to all. This architecture, however, has been switched to service oriented architecture, not being able to meet cope with, increasing data volume and number of access requests. Service oriented architecture, provides a service system, dynamic, elastic and re-contractible where meeting with different users. Also this improves the decision making progresses by spreading spatial information. This article analyzes WebGIS architectures and Technologies by emphasizing architecture.
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References
Alesheikh, A., Helali, H., & Behroz, H. (2002). Web GIS: Technologies and its applications. Symposium on Geospatial Theory Processing and Applications, 18(1), 81–95.
Brandon, P. (1997). GIS online information retrieval, mapping and the internet. OnWord Press.
Çelik, M. Ö., & Çoruhlu, Y. E. (2021). Land Management within This Framework of Sustainable Protected Areas in Turkey. Turkish Journal of Land Management, 3(1), 40-52.
Çoruhlu, Y. E., & Çelik, M. Ö. (2017). Protected areas in land management in our country. 2nd International Conference on Advanced Engineering Technologies, Bayburt, 21-23 September 2017.
Çoruhlu, Y. E., Çelik, M. Ö., Demir, O., & Yıldız, O. (2017). GIS applications in land management of protected areas. Proceedings Book of DOKAP Region International Tourism Symposium, Trabzon, Türkiye, 295-308.
Erbaş, M., & Taştan, H. (N.D.). Serving and Using Digital Maps On Internet-Intranet Environment. Journal of Geomatics,32–49.
Esri. (2021). Retrieved June 07, 2021 from https://www.esri.com/library/userconf/proc00/professional/p
Gillavry, E. M. (2000) Cartographic aspects of Web GIS-software [Doctoral Thesis, Utrecht University]. Utrecht.
Güleç Korumaz, A., Dülgerler, O. N., & Yakar, M. (2011). Digital techniques in cultural heritage documentation. Selçuk University Journal of Engineering, Science and Technology, 26(3), 67-83.
Gümüşay, Ü. (2019). Web based geographic information systems. AKU J. Sci. Eng., 17(2017), 215-222.
HARITA. (2021). HARITA. Retrieved June 07, 2021 from http://www.harita.gov.tr/
ISO/TC211. (2000). New York Item Proposal: Geographic Information-Web Map Server Interface. ISO.
KBS. (2021). KBS. Retrieved June 07, 2021 from http://www.bulut-kbs.gov.tr/
Leukert, K., & Reinhardt, W. (2000). GIS-internet architecture. International Archives of Photogrammetry and Remote Sensing. Vol. XXXIII, Part B4, Amsterdam 2000.
Nayak, S. (2000). GIS data dissemination: A new approach through WEB technology. Rolta India.
OPENGIS. (2021). OPENGIS. Retrieved June 07, 2021 from http://www.opengis.org/
Shouqun, L. (2015). Rise of open source. Office Informatization, 3:6-8.
Strand, E. J. (1998). What’s the right way to web map data? Synergetic Inc.
Taşdemir, Ş., Yakar, M., Ürkmez, A., & İnal, Ş. (2008). Determination of body measurements of a cow by image analysis. In Proceedings of the 9th International Conference on Computer Systems and Technologies and Workshop for PhD Students in Computing, June.
W3C. (2021). W3C. Retrieved June 07, 2021 from http://www.w3.org/
Yakar, M., Yılmaz, H. M., & Mutluoǧlu, Ö. (2010). Comparative evaluation of excavation volume by TLS and total topographic station based methods. Lasers in Eng, 19, 331-345.
Yakar, M., & Doğan, Y. (2018). GIS and three-dimensional modeling for cultural heritages. International Journal of Engineering and Geosciences (IJEG), 3(2), 50-55.
Zhihong, L. (2011). WebGIS: Principles and Practice. Higher Education Press.