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GIS/GPS solutions as efficient tools for sustainable management of vineyards in Kosovo

    Ymer Kuka Affiliation
    ; Perparim Ameti Affiliation
    ; Temenoujka Bandrova Affiliation

Abstract

The main objective of this paper is to analyze and develop a GIS system that includes all necessary information obtained by using GPS and mobile GIS techniques as well. Since several techniques for information management exist, the aim is how to integrate them for a sustainable management of vineyards areas in Kosovo. It has been designed a system, which is able to produce maps, make various analyses based on the requests of the specific users and offers trend orientation for decision making. The JAVA programming language has been used. This provides the most possible flexibility in the data flow and data management. The structure of the data base is proposed to be designed in that way that the textual and geometric data have been processed in a unique data base in PostGIS PostgreSQL technology.Web GIS technology presented in this paper, shows an advantage comparing to the desktop based technology since it enables an access in real time. Foremost, the application offers an access depending on the roles and privileges for different users. Development of a WEB application for viticulture management will improve the efficiency and decision making process as well.Results show numerous capabilities of GIS methodologies to manage the agricultural crops, in this particular case, the vineyards. Further, the results provide insight into information management in a single system and serve as a basis for similar researches in other areas of agriculture in the future.

Keyword : GIS, GPS, map, WEB application, vineyard

How to Cite
Kuka, Y., Ameti, P., & Bandrova, T. (2019). GIS/GPS solutions as efficient tools for sustainable management of vineyards in Kosovo. Geodesy and Cartography, 45(1), 28-36. https://doi.org/10.3846/gac.2019.7083
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Apr 17, 2019
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This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Achilleos, G. (2012, 18-22 June). Allocating the DEM elevation error into its components: The contribution of digitazing and interpolation to the total error. Proceedings vol. 1, 4th International Conference on Cartography and GIS (pp. 139-148). Albena Bulgaria.

Apache Tomcat. (2019). Retrieved from http://tomcat.apache.org

Bandrova, T., Konecny, M., & Yotova, A. (2014, 15-20 June). Cartography development and chalanges on the basis of Big Data. 5th International Conference on Cartography and GIS, Proceedings, 1 (pp. 164-173). Riviera, Bulgaria.

Bootstrap / HTML5. (2019). Retrieved from http://getbootstrap.com

Campbell, E. J., & Shin, M. (2012). Geographic Information System Basics (v. 1.0). Retrieved from http://2012books.lardbucket.org/

Clay, A. SH. (2011). GIS Applications in Agriculture, Vol 3. – In-vasive Species, Taylor and Francis Group LLC, London, New York.

Danko, K. (2012). Springer handbook of geographic information. Berlin, New York: Springer.

Drishti, B. (2012). GIS ne planifikimin e zhvillimit te qendrueshem te nje rajoni. Tiranë.

ESRI. (2009, March). GIS best practices. Using GIS with GPS. Retrieved from www.esri.com/

ESRI. (2014, October). Essays on Geography and GIS, 7. Esri.

Franges, S., Frančula, N., & Lapaine, M. (2002). The future of cartography. Kartografija i geoinformacije, Vol. 1, No. 1.

French, T. G. (1996). Understanding the GPS – An Introduction to the global positioning system. GeoResearch, Inc. USA.

GeoServer. (2019). Retrieved from http://geoserver.org/

GeoWebCache. (2019). Retrieved from http://geowebcache.org/

GSD Geografska Sverigedata Lantmateriet, Document version 1.1. (2015). Product description: GSD – Orthophoto and GSD-Othophoto 25.

Harvey, F. (2008). A Primer of GIS fundamental geographic and cartographic concepts. New York, London: The Guilford Press.

Hibernate Spatial. (2019). Retrieved from http://www.hibernatespatial.org/

Idrizi, B. (2006). Perpilimi i hartave & pergjithesimi Hartografik. FineArt Multimedia, Skopje.

JAVA. (2019). Retrieved from https://www.java.com/en/

Jones, Ph., Drury, R., & McBeath, J. (2011). Using GPS-Enabled mobile computing to augment qualitative interviewing: Two case studies. Field Methods, 23, 173. https://doi.org/10.1177/1525822X10388467/

jQuery. (2019). Retrieved from https://jquery.com/

Kennedy, M. (2002). The global positioning system and GIS an introduction (2nd ed.). London and New York: Taylor & Francis Inc.

Logsdon, T. (1995). Understanding the Navstar GPS, GIS, and IVHS (2nd ed.). Chapman & Hall, USA.

OpenLayers. (2019). Retrieved from http://openlayers.org/

Parker, N. R., & Asencio, K. E. (2009). GIS and spatial analysis for the social sciences, coding, mapping, and modeling. Routledge. https://doi.org/10.4324/9780203929346/

PostGIS. (2019). Retrieved from http://postgis.net//

PostgreSQL. (2019). Retrieved from http://www.postgresql.org/

Pundt, H., & Brinkkotter-Runde, K. (2000). Visualization of spatial data for field based GIS. Computers & Geosciences, 26(1), 51-56. https://doi.org/10.1016/S0098-3004(99)00033-3/

Quan, J., Oudwater, N., Pender, J., & Martin, A. (2001). GIS and participatory approaches in natural resources research. Natural Resources Institute, The University of Greenwich. Published by Natural Resources Institute.

Trimble. (2007). GPS The First Global Navigation Satellite System. Trimble Navigation Limited, USA.