By Inertial Labs
Precision Agriculture is one of the most used cases of autonomy in this century. Recent reports show that by the year 2025, Precision Agriculture is expected to grow to become a 43.4-billion-dollar industry worldwide. For an industry that didn’t begin gaining traction until the 1990s, it’s quite an impressive market.Read more
As it stands, the farming industry has some of the most constrained budgets of any industry on the planet. When it comes to investing in new methods of farming, the most important factor driving change is the cost of labour. If the technology that is involved in the potential methods of Precision Agriculture being considered are more expensive than human efforts to do the same job, then farmers simply have no reason to invest in the change. This creates a demand for inexpensive technology to maximize profitability. Inertial Labs is teaming up with companies across the globe to engineer solutions that are helping farmers become more profitable. Whether you are a large-scale farming operation or a small, local supplier of fresh fruits and vegetables to a farmer's market, automating your processes should be a hassle-free option that increases profit margin.
Methods of Precision Agriculture expand across all levels of the agriculture industry. If you’re environmentally conscious, this is a market for you. Perhaps you prefer to produce crops that are organic, minimizing the amount of exposure they get to fertilizers? Don’t like wasting water? Maybe it’s as simple as you would like a little bit more free time in your day. Whatever the case, automating work and adopting methods in line with the Precision Agriculture industry can lead to some, if not all of the following benefits:
The components of Precision Agriculture can be broken down into two major categories: Software and Hardware. In order to have an effective solution, ideally, the two are used in parallel, feeding information back and forth to constantly drive the best results.
Autonomous Farming Vehicles outfitted with devices like cameras, Inertial Measurement Units (IMUs), Global Positioning System (GPS) receivers, LiDAR sensors, light and heavy response machinery to mitigate poor crop conditions, datalogger, etc. Regardless of what the task is, any vehicle that operates autonomously has to be able to communicate with an outside source and/or be able to detect motion in its own reference frame. Many farming vehicles like seeders, tillers, sprayers, harvesters and surveying drones can be automated using these devices. Currently, this is one of the largest expanding industries across the globe. Autonomous vehicles have expanded farming techniques far beyond those of the 20th century and now embrace methods that help maximize production by identifying soil characteristics; predicting and measuring field drainage both above and below ground; and generating electromagnetic soil maps.
Base Stations are key to autonomous operations on the farm. Real-Time Kinematic (RTK) corrections can be sent from a localized position to ensure that autonomous vehicles are operating with precision accuracy. Some Base Stations, like the one offered by Inertial Labs, can send corrections at different frequencies up to 50 kilometres away. The visual below shows how many Precision Agriculture vehicles use a Base Station to ensure they are getting precision position accuracy.
Integration Solutions are the most critical feature of the agriculture industry. Most products are manufactured and sold at an individual component level, or a full system level. However, many agriculture business operators already have machinery that has been operated reliably for years. Investing in a new system just isn’t practical when it comes to an industry that operates on tight financial constraints. Companies like Inertial Labs offer solutions that can be integrated into desired existing platforms with ease, to make sure that you are paying for performance without the added cost of unnecessary machinery.
The Inertial Labs INS is the one-stop solution for autonomous navigation and communication. The INS supports inputs from cameras, odometers, echo sounders, Doppler Velocity Logs (DVLs), radars, encoders and other external sensors that can be configured to generate solutions utilizing computer vision and machine learning algorithms. The INS also has an internal Inertial Measurement Unit (IMU) that can be made to order depending on consumer needs based on forces, rates of motion, and accuracies needed for the platform.
Mapping Software is a basic necessity when it comes to software needs for Precision Agriculture. The mapping software will give you the ability to view your crops conditions from a birds-eye-view. Depending on the software that is used, different functionality of viewable layers can help you observe characteristics such as soil saturation levels; nitrogen and phosphate levels; estimated profit margins; current conditions of soil or crops; and even locations that have been treated whether from micro-spraying chemicals or mitigating crop conditions (harvesting, weeding, pruning, etc.). All these layers have the ability to be viewed on 2D or 3D models to help you understand exactly how your farm operates and where losses can be mitigated.
Automation Software is currently one of the most lacking tools in the industry today for Precision Agriculture. Although many autopilot software today can be used to generate autonomous flight-paths using a waypoint feature, it is then up to the user to create or purchase expensive personalized software to program functionality of the autonomous vehicle once it arrives at a waypoint. An effective automation software should take into account aiding data from the vehicle and let the user configure actions to be taken when triggered events occur out in the field. For example, If a vehicle utilizing Computer Vision identifies a grape of a specific colour (identified on RBG or CMYK spectrum) it could mean it needs to be: watered, treated with pesticides, fed fertilizer, harvested, or to be removed from the vine. This identification process of the crop can only be done by advanced Machine Learning processes using well-developed automation software that helps a farmer monitor all crop conditions without having to manually identify them.
Inertial Labs offers a complete buddle that is tailored specifically for users that are interested in pursuing the benefits of the Precision Agriculture industry. Industry partners like Pliant are working with Inertial Labs to create practical solutions to the world of Precision Agriculture.
Since their founding in 2008, Pliant has grown to become an innovative and multidisciplinary company specializing in the manufacturing of solutions involving robotics, vision, and controls; on frontiers involving both hardware and software. Pliant began its partnership with Inertial Labs in the early months of 2017 as a platform integrator for supplying complete solutions in the market of Precision Agriculture. In recent years, Pliant has become increasingly involved in the field of autonomy. With companies like Inertial Labs by their side, Pliant has brought autonomous navigation solutions that exceed market expectations in price-value and performance due to their ability to navigate in GNSS-denied environments, mitigating time and financial loses which would previously have been at the expense of the farming industry.
Inertial Labs offers a complete buddle that is tailored specifically for users that are interested in pursuing the benefits associated with the Precision Agriculture industry. Supplied by Inertial Labs, the INS-B accepts RTCM messages from the continuously operating reference station, the RTK Base Station. Depending on the application type, the INS-B can either come as an environmentally sealed IP67 rated enclosure or as an OEM model for easy mounting on platforms where weight is a top priority. The RTK Base Station supports Lefebure NTRIP Caster, a useful tool that configures RTK correction data to be easily accessible over your Internet through the use of a local IP address.
In addition, the post-processing of data is now easier than ever. With the use of Inertial Explorer, a powerful NovAtel software, processing data can now be done in a matter of minutes. Simply create a project, input parameters, and combine data files from the field unit (INS-B) and the RTK Base Station to run the project and correct error. Inertial Labs has a knowledgeable support staff on standby and well-documented manuals to help walk you through processing your data, so you can be confident that regardless of your experience level, processing of results can be done with ease.
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