870 research outputs found
CROP HEIGHT ESTIMATION WITH UNMANNED AERIAL VEHICLES
An unmanned aerial vehicle (UAV) can be configured for crop height estimation. In some examples, the UAV includes an aerial propulsion system, a laser scanner configured to face downwards while the UAV is in flight, and a control system. The laser scanner is configured to scan through a two - dimensional scan angle and is characterized by a maxi mum range. The control system causes the UAV to fly over an agricultural field and maintain, using the aerial propulsion system and the laser scanner, a distance between the UAV and a top of crops in the agricultural field to within a programmed range of distances based on the maximum range of the laser scanner. The control system determines, using range data from the laser scanner, a crop height from the top of the crops to the ground
Local Motion Planner for Autonomous Navigation in Vineyards with a RGB-D Camera-Based Algorithm and Deep Learning Synergy
With the advent of agriculture 3.0 and 4.0, researchers are increasingly
focusing on the development of innovative smart farming and precision
agriculture technologies by introducing automation and robotics into the
agricultural processes. Autonomous agricultural field machines have been
gaining significant attention from farmers and industries to reduce costs,
human workload, and required resources. Nevertheless, achieving sufficient
autonomous navigation capabilities requires the simultaneous cooperation of
different processes; localization, mapping, and path planning are just some of
the steps that aim at providing to the machine the right set of skills to
operate in semi-structured and unstructured environments. In this context, this
study presents a low-cost local motion planner for autonomous navigation in
vineyards based only on an RGB-D camera, low range hardware, and a dual layer
control algorithm. The first algorithm exploits the disparity map and its depth
representation to generate a proportional control for the robotic platform.
Concurrently, a second back-up algorithm, based on representations learning and
resilient to illumination variations, can take control of the machine in case
of a momentaneous failure of the first block. Moreover, due to the double
nature of the system, after initial training of the deep learning model with an
initial dataset, the strict synergy between the two algorithms opens the
possibility of exploiting new automatically labeled data, coming from the
field, to extend the existing model knowledge. The machine learning algorithm
has been trained and tested, using transfer learning, with acquired images
during different field surveys in the North region of Italy and then optimized
for on-device inference with model pruning and quantization. Finally, the
overall system has been validated with a customized robot platform in the
relevant environment
Building an Aerial-Ground Robotics System for Precision Farming: An Adaptable Solution
[No abstract available
Building an Aerial-Ground Robotics System for Precision Farming: An Adaptable Solution
The application of autonomous robots in agriculture is gaining increasing
popularity thanks to the high impact it may have on food security,
sustainability, resource use efficiency, reduction of chemical treatments, and
the optimization of human effort and yield. With this vision, the Flourish
research project aimed to develop an adaptable robotic solution for precision
farming that combines the aerial survey capabilities of small autonomous
unmanned aerial vehicles (UAVs) with targeted intervention performed by
multi-purpose unmanned ground vehicles (UGVs). This paper presents an overview
of the scientific and technological advances and outcomes obtained in the
project. We introduce multi-spectral perception algorithms and aerial and
ground-based systems developed for monitoring crop density, weed pressure, crop
nitrogen nutrition status, and to accurately classify and locate weeds. We then
introduce the navigation and mapping systems tailored to our robots in the
agricultural environment, as well as the modules for collaborative mapping. We
finally present the ground intervention hardware, software solutions, and
interfaces we implemented and tested in different field conditions and with
different crops. We describe a real use case in which a UAV collaborates with a
UGV to monitor the field and to perform selective spraying without human
intervention.Comment: Published in IEEE Robotics & Automation Magazine, vol. 28, no. 3, pp.
29-49, Sept. 202
Automated Mobile System for Accurate Outdoor Tree Crop Enumeration Using an Uncalibrated Camera.
This paper demonstrates an automated computer vision system for outdoor tree crop enumeration in a seedling nursery. The complete system incorporates both hardware components (including an embedded microcontroller, an odometry encoder, and an uncalibrated digital color camera) and software algorithms (including microcontroller algorithms and the proposed algorithm for tree crop enumeration) required to obtain robust performance in a natural outdoor environment. The enumeration system uses a three-step image analysis process based upon: (1) an orthographic plant projection method integrating a perspective transform with automatic parameter estimation; (2) a plant counting method based on projection histograms; and (3) a double-counting avoidance method based on a homography transform. Experimental results demonstrate the ability to count large numbers of plants automatically with no human effort. Results show that, for tree seedlings having a height up to 40 cm and a within-row tree spacing of approximately 10 cm, the algorithms successfully estimated the number of plants with an average accuracy of 95.2% for trees within a single image and 98% for counting of the whole plant population in a large sequence of images
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