Automation: including the use of autonomous robots, drones and tractors to make agriculture more efficient. Precision agriculture: which involves applying irrigation, fertilizers and pesticides at varying rates, depending on the needs of the crops, instead of applying them uniformly at established times, quantities and frequencies. Agriculture has come a long way since its humble beginnings more than 10,000 years ago. While our ancestors developed rudimentary practices for the basic cultivation of edible plants, today our agricultural operations involve the careful application of several scientific principles and some of the most interesting technological advances on the market.
In addition, aerial imaging devices can use geographic information system (GIS) technology to analyze the effectiveness of irrigation plans and their effects on land degradation, erosion and drainage. In addition, images so sharp that they make it possible to evaluate the foliage of an individual plant are not only entirely possible, but are actively used to detect pests and diseases, so that crops can be protected from environmental threats. As for the differences between drone and satellite use cases, both can fulfill most of the critical functions of aerial imaging technology, but each has its advantages and disadvantages. Drones tend to capture and transmit information faster, but they can be prohibitively expensive and cannot cover large plots of land at once.
Satellites can generate spectral images to analyze chlorophyll and nitrogen content, but access and availability are sometimes limited due to interruptions and cloud cover. In addition, when it comes to introducing new technologies into your operations, we started with a Microsoft Dynamics 365 framework. This ensures that our product can be updated without problems and that it is always at the cutting edge in terms of integration with new devices and complementary systems. In addition, it is backed by our dedicated IT teams and redundant servers, providing you with a reliable and multifunctional platform for managing data and executing critical processes.
The Quick Stats database is the most complete tool for accessing agricultural data published by the NASS. Allows you to customize your query by product, location, or time period. Quick Stats Lite offers a more structured approach to obtaining the most requested statistics from our online database. The Census Data Query Tool (CDQT) is a web-based tool that is available to access and download table-level data from the publication of volume 1 of the Census of Agriculture.
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Many thanks to farmers, ranchers and producers across the country who voluntarily participate in the censuses and surveys conducted by the U.S. National Agricultural Statistics Service (NASS). UU. They are the strength behind the census of agricultural information, agricultural inventory, production, prices and the environment produced by NASS.
We appreciate your support and cooperation. They are the cornerstone of the United States food and fiber system. Indoor vertical farming can increase crop yields, overcome limited land area, and even reduce the impact of agriculture on the environment by reducing the distance traveled in the supply chain. Vertical indoor agriculture can be defined as the practice of growing products piled on top of each other in a closed and controlled environment.
By using vertically mounted grow racks, it significantly reduces the amount of land space needed to grow plants compared to traditional growing methods. This type of cultivation is often associated with urban and urban agriculture because of its ability to thrive in limited space. Vertical farms are unique in that some configurations don't require soil for plants to grow. Most are hydroponic, where vegetables are grown in a container of nutrient-rich water, or aeroponics, where plant roots are systematically sprayed with water and nutrients.
Instead of natural sunlight, artificial grow lights are used. From sustainable urban growth to maximizing crop yields with reduced labor costs, the benefits of vertical indoor agriculture are evident. Vertical farming can control variables such as light, humidity and water to measure accurately throughout the year, increasing food production with reliable harvests. Reducing water and energy use optimizes energy conservation: vertical farms use up to 70% less water than traditional farms.
Labor is also significantly reduced through the use of robots to manage harvesting, planting and logistics, which solves the challenge faced by farms due to the current labor shortage in the agricultural industry. Agricultural automation, often associated with “intelligent agriculture”, is a technology that makes farms more efficient and automates the agricultural or livestock production cycle. More and more companies are working on robotic innovation to develop drones, autonomous tractors, robotic harvesters, robots with automatic irrigation and sowing. While these technologies are quite new, the industry has seen an increasing number of traditional agricultural companies adopt agricultural automation in their processes.
As the market has grown dramatically, it has also experienced clear trends in recent years. Modern greenhouses are increasingly using technology and are using LED lights and automated control systems to perfectly adapt the growing environment. Successful greenhouse companies are significantly expanding their cultivation facilities and have located their cultivation facilities close to urban centers to capitalize on the growing demand for local food, regardless of the season. To achieve these feats, the greenhouse industry is also increasingly turning to capital, using venture funds and other sources to build the infrastructure needed to compete in today's market.
Agriculture is undergoing an evolution: technology is becoming an indispensable part of all commercial farms. New precision agriculture companies are developing technologies that allow farmers to maximize yields by controlling all the variables of agriculture, such as humidity levels, pest stress, soil conditions and microclimates. By providing more precise techniques for planting and cultivating, precision agriculture allows farmers to increase efficiency and manage costs. .
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