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.
Technological advances in the agricultural sector meet the growing demand for agricultural automation, digitalization and sustainability. Emerging agricultural trends mark a shift towards intelligent agriculture and the efficient use of time and resources, while reducing crop losses. Smart agriculture is an emerging concept that implements technologies such as the Internet of Things (IoT), computer vision and artificial intelligence (AI) for agriculture. Robots and drones are accelerating agricultural automation by replacing manual agricultural operations, such as picking fruits, removing weeds or spraying water.
Drone and satellite images, together with the Global Positioning System (GPS), provide a high-resolution, location-specific view of the field. In addition, IoT devices, powered by sensor technology, collect real-time field data that allows farmers to make data-based decisions. In addition, the widespread adoption of precision agriculture and indoor agriculture in recent years has boosted the growth of IoT in agriculture. Taken together, these technological innovations generate disruptive and sustainable changes in agricultural practices.
The goal is not only to improve the overall quality and quantity of crops and to improve livestock management, but also to achieve the ultimate goal of a sustainable future. By 2050, demand for food will increase by 70%, in line with rapid population growth. A UN study found that around 9.9% of the world's population is still hungry, so the idea of feeding nearly 10 billion mouths is a daunting prospect. Since environmental changes are difficult to predict, we must resort to innovation in agricultural technology.
Precision agriculture is an agricultural resource management strategy that collects, processes and evaluates data and provides information to help farmers optimize and increase soil quality and productivity. After discovering that birds are sensitive to the color green, a researcher from the University of Rhode Island helped design a laser scarecrow, which projects green laser light. Humans don't see light in sunlight, but it can extend 600 feet across a field to scare birds before destroying crops. The first tests with laser scarecrows found that the devices can minimize damage to crops by reducing the population of birds around farmland by 70 to 90%.
According to Agritech Tomorrow, population growth and demand for food mean that farmers will need to increase agricultural production by at least 23% to maintain our current standard of living. Therefore, losing all yields due to pests is a major problem as the world population grows. Irrigation is a vital method of providing water to drylands that generally do not have enough rainfall to be arable. However, while this is a crucial aspect of agriculture today, many farmers still irrigate their fields with unnecessary amounts of water in the same way as the Mesopotamians did more than 4,000 years ago.
Innovation and technology in agriculture offer farmers more sustainable ways to provide sufficient water to plants. For example, N-Drip, a microdrip irrigation system, allows water to drip slowly to plant roots, creating the right environment for crops to thrive. Technology reduces water use by up to 50% and improves crop quality. From advances in precision agriculture to agricultural automation, genetics and water management technology, innovations in agricultural technology provide the means for smarter, safer and more productive agriculture.
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