GIS-driven agriculture: Pioneering precision farming and promoting sustainable agricultural practices
1 Department of Agricultural Economics, Ladoke Akintola University of Technology, Nigeria.
2 Department of Agriculture Economics, Anambra State Polytechnic, Mgbakwu, Nigeria.
Review
World Journal of Advanced Science and Technology, 2024, 06(01), 057–072.
Article DOI: 10.53346/wjast.2024.6.1.0047
Publication history:
Received on 01 July 2024; revised on 10 August 2024; accepted on 13 August 2024
Abstract:
The integration of Geographic Information Systems (GIS) in agriculture is pioneering precision farming techniques and promoting sustainable agricultural practices. This review explores how GIS technology transforms traditional farming methods by providing detailed spatial analysis and real-time data, enhancing efficiency, productivity, and environmental stewardship. GIS-driven agriculture leverages spatial data and mapping tools to monitor and manage farming activities with high precision. By integrating data on soil properties, crop health, weather patterns, and topography, GIS provides farmers with comprehensive insights into their fields. This precision enables targeted interventions, such as variable rate applications of fertilizers and pesticides, optimizing inputs while minimizing waste and environmental impact. One of the primary benefits of GIS in agriculture is its ability to enhance crop management. Through remote sensing and satellite imagery, GIS technology allows for the continuous monitoring of crop conditions. This capability helps detect issues such as pest infestations, nutrient deficiencies, and water stress early, enabling timely and precise remedial actions. Consequently, farmers can maintain healthier crops, improve yields, and reduce losses. GIS also plays a critical role in resource management and environmental conservation. By mapping field variability and soil types, GIS helps farmers implement site-specific management practices, such as contour farming and buffer strips, that reduce soil erosion and nutrient runoff. Additionally, GIS facilitates efficient water management by identifying optimal irrigation zones and schedules, thus conserving water resources and promoting sustainable water use. Furthermore, GIS-driven agriculture supports climate-smart farming practices. By analyzing historical weather data and climate models, GIS helps predict future climatic conditions and their potential impacts on agriculture. This information enables farmers to adopt adaptive strategies, such as selecting climate-resilient crop varieties and adjusting planting schedules, to mitigate the adverse effects of climate change. Moreover, GIS technology fosters sustainable land use planning. It aids in identifying suitable areas for crop rotation, cover cropping, and agroforestry, enhancing soil health and biodiversity. GIS also supports precision livestock farming by monitoring grazing patterns and optimizing pasture management. In conclusion, GIS-driven agriculture is at the forefront of precision farming and sustainable agricultural practices. By providing actionable insights through detailed spatial analysis, GIS enhances efficiency, productivity, and environmental stewardship in farming. As GIS technology continues to evolve, its application in agriculture will be crucial for meeting the growing food demands while ensuring sustainability and resilience in the face of climate change.
Keywords:
GIS-Driven Agriculture; Sustainable; Precision Farming; Promoting; Practices
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