Precision agriculture gives farmers the ability to more effectively use agricultural inputs, including fertilizers, pesticides, tillage and irrigation water. A more efficient use of inputs means higher yield and (or) quality of crops, without polluting the environment. Precision agriculture systems are dynamically developing management systems. They allow farmers to solve a whole range of problems.
At the same time, precision agriculture includes a wide range of tools that producers must master to get the most out of their production. Precision agriculture uses modern technologies, such as satellite imagery or field maps, to improve the quality and profitability of crops. Precision agriculture, according to NAS, should play an important role in making agriculture more sustainable, without compromising farmers' production or incomes. Farmers like Henry work all their lives to manage their land and leave it in better condition for future generations, and Henry himself is optimistic about the future.
The idea that differentiates precision agriculture from traditional methods is the application of variable speed (VRA). Variable Rate Technology (VRT) allows farmers to precisely vary the amount and where they use inputs (seeds, fertilizers or water) based on overlapping data sources, such as soil maps, maps of previous harvest performance, or images collected with drones, airplanes or satellites. Computer support is required to analyze the data collected by other components of precision agriculture technology and make them accessible in formats such as maps, graphs, tables or reports. Farmers are facing increasing regulatory and market pressure to make their operations more sustainable, and technology is creating new economic and environmental opportunities for agriculture.
Harvester performance monitors generate yield maps during the harvest period by measuring the amount of harvest harvested at precise geolocated points in a field using GPS and GIS technology. When farmers don't take into account these inherent differences and don't provide nutrients and treatment uniformly, they are providing too many resources to good areas and not enough to poor areas. The first agricultural revolution, which took place between 1900 and 1930, consisted of mechanizing agriculture, which allowed each farmer to produce enough for 26 people. As precision agriculture software, EOSDA Crop Monitoring offers the possibility of zoning any field based on vegetation indices.
They are essential for crop consultants and agricultural centers; however, the support network available to farmers who want to learn how to use and implement these technologies on their own has grown tremendously in recent years, making the process more effective than ever. Once he identifies a site with deviations, the farmer can send an explorer to prepare a report based on the data collected during the inspection. This is a list of specific precision agriculture technologies commonly used by precision agriculture farmers. It focuses on collecting and analyzing data from agricultural PIOTs, which include sensors, drones and robots to record the data, and software as a service (SaaS) can be used to adapt to precision agriculture systems.
Precision agriculture dates back to the 1950s and 60s, when the first GPS (global positioning system) satellites were launched.
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