From Soil To Satellite: Five Ways IoT Will Impact Modern Agriculture

Agricultural technology is an ever-important branch of development across technologies. AgriTech engages solutions within multiple technology departments, including AI, machine learning, and the Internet of Things (IoT).
Between 2021 and 2023, the integration of IoT into modern agriculture, often referred to as "precision agriculture" or "smart farming," has seen significant advancements. IoT has played a vital role in monitoring soil conditions, water usage, crop health, and even livestock management. These technologies enable real-time data collection and analysis, optimizing farming processes and increasing productivity while conserving resources.
By 2022, the global IoT market in agriculture had reached $11.4 billion, and it is projected to grow to $18.1 billion by 2026 at an annual growth rate of around 9.8%. This growth is driven by the increasing demand for food due to population growth and the need for sustainable farming practices.

Let’s find out the role of IoT in the future of modern agriculture.


How The IoT Will Impact Modern Agriculture

1. Sensing Capabilities In Precision Farming

While working potentially toward one of the most significant applications of the IoT, precision farming can be applauded for having gained hardly enough recognition. Such innovations could, based on data analysis, contribute towards improving production amidst a food crisis and give a few clues about what can be done to prevent the situation from worsening

The IoT has enabled for the multifaceted analyses of farming processes, including crop and cattle management, weather conditions, soil quality, and staff performance. Such comprehensive data collection sheds light on the progress and development on the farm, converting them into informed bases for making decisions. Besides this, IoT adoption produces a greater scope in ways, such as saving resources and waste reduction.

2.  Intelligent Water Management: IoT devices can assist in the optimization of water use in agriculture. Monitoring soil moisture content, weather conditions, and crop types through sensing systems can lead to more precise irrigation. Water savings are expected to be quite substantive through the use of the technology.

-

3. Yield Monitoring and Crop Management: With the capability of accessing crop health and soil conditions, IoT solutions guide farmers through educated decision-making for harvest and planting, resulting in better management of crops and reduced waste of resources.


4. Environmental Monitoring: The real-time monitoring of various conditions has been enabled by leveraging a set of interconnected devices, such as sensors and drones. In conjunction with cloud computing and AI, these combined technologies foster advanced data processing and predictive analytics in crop yields and disease detection. This means farming processes can be automated, and input resources can be optimized and adapted to climate change.


5. Supporting Livestock Management:- Some IoT systems can facilitate real-time monitoring of environmental factors affecting livestock, such as air quality, ventilation, climate conditions, and light—helping farmers respond quickly to abnormal conditions for better animal welfare. These technologies can also provide location tracking and virtual boundary setting for livestock, allowing livestock to be monitored and dissuading theft by alerts when an animal goes beyond a particular area.

The adoption of IoT systems will help in optimizing the feeding process. Such systems create a convenience where automated systems can feed livestock by dispensing accurate amounts of feed, ensuring complete nutrition and reducing feed wastage. Such systems would also help regulate water levels in tanks and troughs and automate the refill intervals to sustain a steady supply of water.

6. Smart Irrigation Systems: IoT-enabled irrigation systems can draw optimal amounts of water into the soil depending on the moisture level of the soil and weather predictions. Such systems conserve water and allow the crops to grow under optimum growth conditions for irrigation systems. Such systems may comprise different kinds of sensors, including:

Intelligent irrigation systems use various sensors that transmit real-time data to a central system, thereby automatically controlling water pumps based on moisture or thermal levels detected. Farmers are capable of controlling these systems via cloud-based platforms or mobile applications, making them capable of making necessary changes in real time and overseeing the process.

 

Challenges and Opportunities:

 Many opportunities are bound to be developed that will surely enhance farming practices while at the same time resulting in environmentally sustainable agriculture, from the viewpoint of the global climate crisis. But it does also come with certain challenges. Since the initial CAPEX is gigantic, not many can afford it, mainly in poorer nations. The complexity of such intelligent IoT ecosystems could also act as a prominent roadblock.

 

Comments (0)

This post does not have any comments. Be the first to leave a comment below.


Post A Comment

You must be logged in before you can post a comment. Login now.

Featured Product

How to overcome GNSS limitations with RTK correction services

How to overcome GNSS limitations with RTK correction services

Although GNSS offers ubiquitous coverage worldwide, its accuracy can be hindered in some situations - signals can be attenuated by heavy vegetation, for example, or obstructed by tall buildings in dense urban canyons. This results in signals being received indirectly or via the multipath effect, leading to inaccuracy, or even blocked entirely. Unimpeded GNSS positioning in all real world scenarios is therefore unrealistic - creating a need for supporting technologies, such as real time kinematic (RTK) positioning and dead reckoning, to enable centimeter-accuracy for newer mass-market IoT devices.