Unmanned aerial vehicles – better known as drones – have been used commercially since the early 1980s.
According to www.technologyreview.com, today, practical applications for drones are expanding faster than ever in a variety of industries, thanks to robust investments and the relaxing of some regulations governing their use. Responding to the rapidly evolving technology, companies are creating new business and operating models for UAVs.
The total addressable value of drone-powered solutions in all applicable industries is significant—more than $127bn, according to a recent PwC analysis.
Among the most promising areas is agriculture, where drones offer the potential for addressing several major challenges. With the world’s population projected to reach nine billion people by 2050, experts expect agricultural consumption to increase by nearly 70 per cent over the same time period. In addition, extreme weather events are on the rise, creating additional obstacles to productivity.
Agricultural producers must embrace revolutionary strategies for producing food, increasing productivity, and making sustainability a priority. Drones are part of the solution, along with closer collaboration between governments, technology leaders, and industry.
Six options for agricultural drones
Drone technology will give the agriculture industry a high-technology makeover, with planning and strategy based on real-time data gathering and processing.
PwC estimates the market for drone-powered solutions in agriculture at $32.4bn. Following are six ways aerial and ground-based drones will be used throughout the crop cycle:
Soil and field analysis
Drones can be instrumental at the start of the crop cycle. They produce precise 3-D maps for early soil analysis, useful in planning seed planting patterns. After planting, drone-driven soil analysis provides data for irrigation and nitrogen-level management.
Start-ups have created drone-planting systems that achieve an uptake rate of 75 per cent and decrease planting costs by 85 per cent. These systems shoot pods with seeds and plant nutrients into the soil, providing the plant all the nutrients necessary to sustain life.
Distance-measuring equipment—ultrasonic echoing and lasers such as those used in the light-detection and ranging, or LiDAR, method—enables a drone to adjust altitude as the topography and geography vary, and thus avoid collisions.
Consequently, drones can scan the ground and spray the correct amount of liquid, modulating distance from the ground and spraying in real time for even coverage. The result is increased efficiency with a reduction in the amount of chemicals penetrating into groundwater. In fact, experts estimate that aerial spraying can be completed up to five times faster with drones than with traditional machinery.
Vast fields and low efficiency in crop monitoring together create farming’s largest obstacle. Monitoring challenges are exacerbated by increasingly unpredictable weather conditions, which drive risk and field maintenance costs. Previously, satellite imagery offered the most advanced form of monitoring. But there were drawbacks. Images had to be ordered in advance, could be taken only once a day, and were imprecise.
Further, services were extremely costly and the images’ quality typically suffered on certain days. Today, time-series animations can show the precise development of a crop and reveal production inefficiencies, enabling better crop management.
Drones with hyperspectral, multispectral, or thermal sensors can identify which parts of a field are dry or need improvements. Additionally, once the crop is growing, drones allow the calculation of the vegetation index, which describes the relative density and health of the crop, and show the heat signature, the amount of energy or heat the crop emits.
It is essential to assess crop health and spot bacterial or fungal infections on trees. By scanning a crop using both visible and near-infrared light, drone-carried devices can identify which plants reflect different amounts of green light and NIR light. This information can produce multispectral images that track changes in plants and indicate their health.
A speedy response can save an entire orchard. In addition, as soon as a sickness is discovered, farmers can apply and monitor remedies more precisely. These two possibilities increase a plant’s ability to overcome diseases. And in the case of crop failure, the farmer will be able to document losses more efficiently for insurance claims.
Looking further into the future, UAVs might involve fleets, or swarms, of autonomous drones that could tackle agricultural monitoring tasks collectively, as well as hybrid aerial-ground drone actors that could collect data and perform a variety of other tasks.
So, what’s slowing the progress of drones in agriculture? Beyond the barriers to widespread drone adoption in all industries—safety of drone operations, privacy issues, and insurance coverage questions—the biggest agricultural concern is the type and quality of data that can be captured. To address this, the industry will push for more sophisticated sensors and cameras, as well as look to develop drones that require minimal training and are highly automated.
sandboxing is a software management strategy that isolates applications from critical system resources and other programmes. It provides an extra layer of security that prevents malware or harmful applications from negatively affecting your system, www.techterms.com says.
Without sandboxing, an application may have unrestricted access to all system resources and user data on a computer. A sandboxed app on the other hand, can only access resources in its own “sandbox.”
An application’s sandbox is a limited area of storage space and memory that contains the only resources the programme requires. If a programme needs to access resources or files outside the sandbox, permission must be explicitly granted by the system.
For example, when a sandboxed app is installed in OS X, a specific directory is created for that application’s sandbox. The app is given unlimited read and write access to the sandboxed directory, but it is not allowed to read or write any other files on the computer’s storage device unless it is authorised by the system. This access is commonly granted using the Open or Save dialog box, both of which require direct user input.
While sandboxing provides added security for users, it can also limit the capabilities of an application. For example, a sandboxed app may not allow command line input since the commands are run at a system level. Utilities such as backup programmes and keyboard shortcut managers may not be granted sufficient permissions to function correctly. For this reason, some programsme cannot be sandboxed.
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