Geospatial Approach for Integrated Command Area Management

AbstractAmong the goals set by the United Nations 2030 agenda for sustainable development to address the economic component of sustainable development goal (SDG) target 6.4, More Crop Per Drop happens to be the universal motto for using water more efficiently in the agricultural sector. A fool-proof...

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Veröffentlicht in:	Journal of irrigation and drainage engineering 2022-04, Vol.148 (4)
Hauptverfasser:	Ramadasa, Abhilash, Basappa, Venkatesh, Chakragiri, Srinivasa Venkataramaiah, Patankar, Digvijay Babasaheb
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural industry Cropping systems Decision support systems Economics Geographical distribution Integrated approach International organizations Irrigation Irrigation efficiency Irrigation water Linear programming Optimization Optimization techniques Sustainability Sustainable development Sustainable Development Goals Technical Papers Water allocation
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container_title	Journal of irrigation and drainage engineering
container_volume	148
creator	Ramadasa, Abhilash Basappa, Venkatesh Chakragiri, Srinivasa Venkataramaiah Patankar, Digvijay Babasaheb
description	AbstractAmong the goals set by the United Nations 2030 agenda for sustainable development to address the economic component of sustainable development goal (SDG) target 6.4, More Crop Per Drop happens to be the universal motto for using water more efficiently in the agricultural sector. A fool-proof, transparent, integrated approach across different governing sectors is essential to optimally allocate the limited available resources amid the competing agricultural activities. This study has attempted to integrate a linear programming model on a geospatial platform to develop a spatial decision support and management system for integrated command area management. The study shows that the geospatial approach enhances the visualization of conventional optimization outputs under different irrigation efficiencies and fixed water allocation conditions. The geomatic model highlights water-stressed regions with 45% and optimal cropping patterns at 57% irrigation efficiency. The spatial optimization technique suggests geographic distribution of optimal cropping patterns to attain more agricultural productivity per unit of water.
doi_str_mv	10.1061/(ASCE)IR.1943-4774.0001659
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subjects	Agricultural industry Cropping systems Decision support systems Economics Geographical distribution Integrated approach International organizations Irrigation Irrigation efficiency Irrigation water Linear programming Optimization Optimization techniques Sustainability Sustainable development Sustainable Development Goals Technical Papers Water allocation
title	Geospatial Approach for Integrated Command Area Management
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