What Is Agriculture Technology: The modern farm develops in different ways. However, his main focus is on using agricultural technology to increase yields through better planning and intelligent management. By promoting efficient and sustainable agricultural practices, advanced agricultural technology is helping farmers thrive in today’s agricultural industry. Best practices like crop rotation and new farming technologies like monitoring field productivity with machines. And satellite imagery or specialized farming software all impact farm performance.

What Is Agriculture Technology?

Agricultural technology, also known as “agritech”, encompasses a wide range of disciplines and tools that improve agricultural productivity. This includes cars, robots, computers, satellites, drones, mobile devices, and software. The use of big data analytics and artificial intelligence (AI) technologies in agriculture is also an example of how the agricultural sector is embracing technological advances. The changes in agriculture and field management in recent years have been revolutionary. The use of modern, advanced technology in agriculture can be hailed as the latest breakthrough in crop.

Importance of Technology in Agriculture

Agricultural engineering aims to make work in this area easier and more efficient. Every year there are various agricultural innovations and then occasionally new technologies. As agriculture continues to modernize and grow. It is becoming increasingly important for agricultural consultants, food producers, and technical managers to be informed and up-to-date on the latest technology standards.

Water, fertilizers, pesticides, and other inputs are no longer used “by eye” or consistently across the region by large agricultural producers. The use of advanced agricultural technology allows precise use of only the amounts needed in each area, as well as careful adjustment of the treatment of each crop.

Evolution of Agriculture Technology

Technological advances in agriculture are associated with the growth of urban centers and commercial exchanges. In this area, new technological developments are widespread. Nevertheless, the technical model of agricultural production remained largely subsistence-oriented and characterized by low productivity until the beginning of the 20th century. Farming 2.0 began in the late 19th century with the introduction of machines such as the tractor. And later, agricultural technology goes through several development cycles, since the pace of technological development has increased dramatically.

Types Of Precision Agricultural Technology are Now in Use

To increase yield and keep up with the times, farmers need to have a thorough understanding of the latest technological developments and how they are used in agriculture.

GPS Technology In Agriculture

Using GPS data, precision farming technology improves productivity while reducing the wastage of inputs such as seeds, fertilizers, pesticides, and fuel. In addition to providing location-based agricultural information, GPS, when integrated with agricultural management software, can also be used to facilitate vehicle-to-vehicle communication and record-keeping.
The many possible uses of this technology in the agricultural industry include:

• Monitoring and managing field operations;
• Collecting and analyzing data from the fields;
• Accurate soil sampling;
• Yield mapping;
• Navigating and controlling agricultural machinery;
• The ability to operate in low-visibility field conditions like heavy rain or fog.

Robotic Technology In Agriculture

Robotic technology for farm work is a viable option for precision farming needs. As it can perform complex tasks without sacrificing precision. The autonomous operation of such robots can enable continuous field cultivation and improve agricultural productivity and efficiency as the robot can collect information about its surroundings on its own.

Data Collection And Storage

The incorporation of big data into agricultural technology has improved the flow of information, enabled rapid and accurate analysis, and ultimately led to improved decision-making and strategic planning. By analyzing historical agricultural data, we can predict possible outcomes, assess risks and choose the best course of action. Thanks to the development of agricultural technology, more information about farms can collected and stored. Soil pH, relative humidity, nutrient levels, soil moisture, and past weather data are some of the agricultural technology indicators that can derived from field data using agricultural technology.

EOSDA Crop provides extensive information on root and topsoil moisture levels, crop production, crop types, field length, weather conditions, e.g. B. previous precipitation and temperature values, agricultural activities (irrigation, seeding, harvesting), and much more available. Surveillance. With the help of agricultural data presented on the platform. You can analyze the capacity of the field and the previous harvest, as well as make future harvest forecasts in an accessible and simple way. In addition, this information is useful for cooperative management, crop planning, and agricultural hazard identification.

Smart Agriculture Sensors

With the help of agricultural sensors, weather conditions, plant moisture, soil temperature, and fertility, insect infestation and weed areas can determined. Using this data helps farmers, agricultural consultants, insurance brokers, and other stakeholders in the agricultural sector to make informed decisions, resulting in higher farm production at lower costs.

Geographic Information Systems (GIS)

A geographic information system (GIS) is essential for storing, analyzing, and visualizing geographic data for precision farming needs. One of the most important uses of GIS-based agricultural technology in agriculture is the collection of information about regional vegetation, soil, weather, and climate through the use of satellites and drones. In addition, GIS in agriculture allows the use of GPS applications in conjunction with intelligent tools to improve the distribution of fertilizers and pesticides.

With the help of the GIS functions of EOSDA Crop Monitoring you can create field productivity maps with the basic NDVI index in a few years. Using the yield maps. You can easily identify the most productive parts of your field, as well as the under-yielding areas that could benefit from additional fertilizer or other methods of improving field productivity.

Agricultural Drone Technology

Drones, also known as unmanned aerial vehicles (UAVs), are becoming increasingly common in the agricultural industry. Drones can monitor the field from above and report problems such as pests, diseases, and lack of essential nutrients. Agricultural data gives farmers insight into the condition of their fields.

Satellite Remote Sensing Technology In Agriculture

The use of satellites has revolutionized geographic surveillance, significantly increasing both the amount of agricultural data and the then frequency with which it is collected. Satellite sensors monitor, measure and then record electromagnetic radiation. With agricultural satellite technology, e.g. B. current and historical satellite images. You can follow the plant growth throughout the season even in large, inaccessible areas. This information is useful for a variety of purposes, including evaluating the effectiveness of agricultural practices.

To help agricultural producers and landowners make informed decisions, the EOSDA one-stop crop monitoring platform processes satellite imagery data.

Mobile Technology In Agriculture

Agricultural mobile apps are currently expanding their market share and range of functions. By marking a field on a map and monitoring its NDVI crop index over time,

How Does Technology Impact Agriculture?

In the information age, there are more opportunities than ever before to use technology in agriculture. Agricultural businesses rely on technology to improve field management. This is one of the many new ways in which farming has changed.

The use of inputs such as fertilizers and pesticides can reduce the use of advanced agricultural software. Agricultural technology also helps to reduce harmful emissions such as carbon dioxide. This was achieved by simplifying the agricultural production process and then eliminating unnecessary steps. Climate-friendly agriculture helps to solve many challenges in food production by providing specific crop cultivation strategies. Also, mechanization improves the productivity and efficiency of the entire farming operation, including planting, harvesting, and distribution.

Sustainable Prospects For Agriculture Technology

Accelerating technological advancements in farming are having a profound impact on the industry. Agricultural satellite technology is rising to the forefront to better manage inputs, streamline operations, and increase farm productivity. Higher yields and lower maintenance costs translate into greater agricultural earnings. Thus, leveraging satellites in the agricultural sector is a big step toward a more productive and sustainable farming technology that can keep up with the growing need for food around the world.