At all levels of the agriculture and food sector, environmental sustainability is becoming increasingly important. It’s no longer just a question of bringing fruits and vegetables to market. They must also be fruits and vegetables grown in the correct conditions. Consumer demand for sustainable solutions and better food sources. It is expanding, driving up demand for zero-waste and natural products. As a result, there has already been a rise in the use of BioSolutions, contributing to the demand for smarter farm management through precision agriculture.


Empowering Agricultural BioSolutions with Data 

Farming has always progressed, but data has always been difficult to come by until lately. Precision agriculture is no longer merely a pipe dream. We now have the ability to acquire data at micro and macro levels that we didn’t have access to before because of advances in farming technology. For a producer, this includes having access to data from their machinery, sensors that can monitor data from their fields’ soil. And even satellite photography can help them improve the accuracy of their biological input utilization. Rather than depending just on historical trends, growers can now access real-time data pertinent to their crops. They can make decisions to boost their yield by optimizing their farming production at all stages. This is critical when using BioSolutions since they must be applied at specific phases of growth for the best outcomes.

What is Precision Agriculture?

Precision agriculture is now possible for both small and large-scale agricultural operations thanks to technological improvements. Farmers could acquire data and steer agriculture equipment autonomously using GPS-satellite technology back then. Sensors, aerial devices, fixed IoT solutions for precision agriculture, and other technologies are now available to help farmers collect more precise data. Let’s take a closer look at the key goals of employing precision farming technology to better answer the question ‘What is precision farming technology?

What is precision farming technology?

To identify optimal crops with higher yields, gather farming data, including historical, predictive modeling, and environmental insights. By gathering data in real-time, you can improve the farm’s economic and environmental sustainability. Use digital farming data (soil, crop health, weather, and so on) to administer the right quantity of water, fertilizer, and pest control. Predict weather changes and take preemptive measures to deal with them. Precision agriculture decreases agricultural waste while also lowering the environmental effects. It enables farmers to obtain the most production out of each site. As a result, researchers believe precision agriculture is an effective strategy to address global food shortages.

Precision Agriculture
Sensors Technology used in Agriculture

Advantages of precision farming in agriculture

For the time being, farmers are beginning to see the benefits of precision farming with IoT. Technology integration in crop and cattle management is seen by agriculture business owners as a tool to increase decision-making quality, ROI, and overall site security. These are the advantages of precision agriculture in the Internet of Things for today’s farming landscape. The strategy provides a long list of benefits, therefore it’s well worth applying.

  • Agriculture monitoring metrics-A grower will be able to continuously monitor a wide range of parameters, including rainfall levels, the amount and nature of nutrients that crops require to reach their full potential, soil samples, fertiliser inputs, and so on, thanks to digital tools. Farmers may make more informed judgments in all domains with a better understanding of the state of their crops.
  • Decision-making Efficiency-Farmers have long-term access to crucial real-time data. When they utilise precision agriculture sensors to monitor soil moisture, crop health, and nutrient levels. A site manager will be able to recognise patterns and predict changes, potential threats, and yields throughout the harvest and growing season in this manner.
  • Obtaining access to agricultural records-Using technology to manage a farm makes data more accessible. Precision agriculture frees team members from the confines of the office. All relevant data is accessible at any time from any device thanks to cloud-based technologies.
  • More effective crop protection-One of the causes of increased crop and soil pressure is the overuse of pesticides. Farmers frequently use excessive nitrogen to protect the site from crop-damaging insects. Using chemicals is costly, in addition to diminishing the site’s environmental sustainability. One of the most significant advantages of using Internet of Things to implement precision agriculture is the ability to optimise pest control, apply chemicals only when necessary, and preserve crops more effectively.

Sustainability with Precision Agriculture 

One of the most difficult challenges for proponents of sustainable agriculture methods is demonstrating that the long-term benefits of some unsustainable activities outweigh the short-term benefits of some unsustainable practices. The data from Precision Ag instruments reveal both the good and negative effects of agricultural practices. Furthermore, as global demand develops, there is a need for increased yields while maintaining environmental sustainability. Smart agricultural strategies are also useful in this situation. As they can help growers make the most of their current resources. The effects of climate change influence producers who are experiencing weather conditions never seen before in their regions, sustainability is becoming increasingly important. With the help of Precision Agriculture, the greater risk of the unpredictability of such environmental conditions can be addressed to some extent.

Growers in the world are increasingly using a suite of interconnected technologies – monitoring sensors, information systems, and analysis teams. To improve their production, Precision Agriculture is becoming more widely available. The capacity to apply BioSolutions and other sustainable techniques will become much easier. As smart agricultural technology evolves and becomes more available, the benefits will become more apparent. Precision Agriculture is leading the way in precision farming by giving growers access to technology. Precision Agriculture is part of the Open Innovation initiative, which gives everyone free access to cutting-edge thinking, IT, R&D, agrochemistry, BioSolutions.

Progressive Technology used in Precision Agriculture

  • Sensors-They can detect a variety of biomolecular, chemical, optical, thermal, electrical, radiation, and biological metrics to provide a 360-degree perspective of a crop’s health. Farmers may track the health of their cattle in real time by attaching health monitoring devices to them.
  • Software for precision farming-In IoT-based precision agriculture technologies, controller tools are commonly used. IoT enhances software maintenance (automated equipment updates, for example) and brings new farm management tools (managing a safe-driving tractor remotely via a controller). The potential of current precision agriculture and IoT allows for simultaneous control of dozens of equipment pieces.
  • Protocols for connectivity-While some network protocols (such as ZigBee or Wi-Fi) function well over short distances. It is the long-range protocols that are most useful for precision agriculture. Cellular connections, LoRaWAN, LPWAN, and a few others are the most extensively used connectivity protocols in intelligent farming.
  • Tools for tracking your location- Satellites are commonly used to assess soil water content, crop biomass, and a variety of other variables. Crop insurance firms, governments, scientists, politicians, and commodity groups use the data collected by connected GPS satellites or a location tracking service. Farmers may expect increased precision in data collection. And analysis, as well as the ability to monitor all crop farming activities. And performance and receive a big-picture view of farm sites, thanks to these technologies.

Sensors and Mapping Technology

Sensors and mapping technology enable farmers to increase harvests while using the least amount of resources possible. Farmers have been able to map crop fields more accurately than ever before because of this technology, which allows for the monitoring of field conditions and the delivery of fertilizer and weed treatments according to the individual needs of plants. Crop monitoring has aided early precision agriculture users in obtaining optimal fertilizer and pH correction recommendations. To refresh your memory, there are four types of sensing technology used in commercial agriculture:

  • GPS satellite signals-GPS satellite signals are used by location sensors to identify the latitude, longitude, and altitude of cropland.
  • Optical sensors-Optical sensors detect soil qualities using light. The sensors can help examine clay, organic matter, and moisture levels in soil by measuring distinct frequencies of light reflection.
  • Electrochemical sensors-Electrochemical sensors detect specific ions in the soil and provide data on pH and nutrient levels in the soil.
  • Mechanical sensors-Mechanical sensors measure soil compaction.Tensiometers, a common form of mechanical sensor used in irrigation planning, detect the force exerted by the roots when absorbing water.Some of the most significant gains in both irrigation management.
  • Drone-Drone pesticide spraying, for example, produces outcomes that are immeasurably superior to traditional approaches, are faster. And produce better crops at cheaper costs. Krish-e smart solutions are available for purchase as entire systems as well as rental and subscription options.So they may be deployed on farms of any size.Drone pesticide spraying is supported by the next generation of precision agriculture, ensuring effective application and maximum coverage.

Farmers Problem

  • Pest Control For Grapes Reduces Pesticide Use-Diseases/pests, excessive pesticide use, and a dearth of qualified agronomists during the harvest season. To spot illnesses in the grape vines are all problems that grape farmers in India confront.Detecting and geolocating diseases, allowing for early and accurate management of infestations.
  • To Optimize Fertilizer Use, Use Soil Mapping-The soil condition on your farm isn’t uniform. And the capacity to soak fertilisers isn’t uniform either. We use our science maps to show you the optimal degree of fertilising for different regions of your farm.
  • Sugarcane Harvesting at Its Finest-Is your sugarcane in top condition and ready to be harvested? So that you get the most out of your sugarcane this technology .It will tell you when it’s at its peak and ready to harvest. It will also assist you in planning your harvest plans ahead of time.

Related Blog: Digital Agriculture in India: Challenges and Opportunities