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Collect information about soil or field attributes, yield data, or field boundaries, using field data recorders and basic geographic information systems (GIS).
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Demonstrate the applications of geospatial technology, such as Global Positioning System (GPS), geographic information systems (GIS), automatic tractor guidance systems, variable rate chemical input applicators, surveying equipment, or computer mapping software.
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Prepare reports in graphical or tabular form, summarizing field productivity or profitability.
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Contact equipment manufacturers for technical assistance, as needed.
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Participate in efforts to advance precision agriculture technology, such as developing advanced weed identification or automated spot spraying systems.
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Install, calibrate, or maintain sensors, mechanical controls, GPS-based vehicle guidance systems, or computer settings.
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Identify spatial coordinates, using remote sensing and Global Positioning System (GPS) data.
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Compare crop yield maps with maps of soil test data, chemical application patterns, or other information to develop site-specific crop management plans.
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Provide advice on the development or application of better boom-spray technology to limit the overapplication of chemicals and to reduce the migration of chemicals beyond the fields being treated.
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Program farm equipment, such as variable-rate planting equipment or pesticide sprayers, based on input from crop scouting and analysis of field condition variability.
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Identify areas in need of pesticide treatment by analyzing geospatial data to determine insect movement and damage patterns.
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Analyze data from harvester monitors to develop yield maps.
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Advise farmers on upgrading Global Positioning System (GPS) equipment to take advantage of newly installed advanced satellite technology.
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Document and maintain records of precision agriculture information.
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Draw or read maps, such as soil, contour, or plat maps.
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Apply precision agriculture information to specifically reduce the negative environmental impacts of farming practices.
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Analyze geospatial data to determine agricultural implications of factors such as soil quality, terrain, field productivity, fertilizers, or weather conditions.
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Analyze remote sensing imagery to identify relationships between soil quality, crop canopy densities, light reflectance, and weather history.
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Divide agricultural fields into georeferenced zones, based on soil characteristics and production potentials.
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Create, layer, and analyze maps showing precision agricultural data, such as crop yields, soil characteristics, input applications, terrain, drainage patterns, or field management history.
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Use geospatial technology to develop soil sampling grids or identify sampling sites for testing characteristics such as nitrogen, phosphorus, or potassium content, pH, or micronutrients.
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Recommend best crop varieties or seeding rates for specific field areas, based on analysis of geospatial data.