Vision-based adaptive variable rate spraying approach for unmanned aerial vehicles

The rapid developments of unmanned aerial vehicles (UAV) and vision sensor are contributing a great reformation in precision agriculture. Farmers can fly their UAV spraying pesticides around their crop fields while staying at their remote control room or any place that is separated from their farm l...

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Bibliographic Details
Published in:International journal of agricultural and biological engineering 2019-05, Vol.12 (3), p.18-26
Main Authors: Wang, Linhui, Lan, Yubin, Yue, Xuejun, Ling, Kangjie, Cen, Zhenzhao, Cheng, Ziyao, Liu, Yongxin, Wang, Jian
Format: Article
Language:English
Subjects:
Agricultural land
Agricultural management
Agriculture
Agrochemicals
Algorithms
Aviation
Control rooms
Crop diseases
Crop dusting
Crop fields
Design
Farms
Feature extraction
Fuzzy control
Land use
Nonlinear systems
Oryza
Parameter identification
Pesticides
Planting management
Precision farming
Remote control
Researchers
Rice
Rice fields
Sensors
Spraying
Support vector machines
Target recognition
Unmanned aerial vehicles
Vehicles
Vision
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Summary:The rapid developments of unmanned aerial vehicles (UAV) and vision sensor are contributing a great reformation in precision agriculture. Farmers can fly their UAV spraying pesticides around their crop fields while staying at their remote control room or any place that is separated from their farm land. However, there is a common phenomenon in rice planting management stage that some empty areas are randomly located in farmland. Therefore, a critical problem is that the waste of pesticides that occurs when spraying pesticides over rice fields with empty areas by using the common UAV, because it is difficult to control the flow accuracy based on the empty areas changing. To tackle this problem, a novel vision-based spraying system was proposed that can identify empty areas automatically while spraying a precise amount of pesticides on the target regions. By this approach, the image was preprocessed with the Lucy-Richardson algorithm, then the target area was split from the background with k-means and the feature parameters were extracted, finally the feature parameters were filtered out with a positive contribution which would serve as the input parameters of the support vector machine (SVM) to identify the target area. Also a fuzzy control model was analyzed and exerted to compensate the nonlinearity and hysteresis of the variable rate spraying system. Experimental results proved that the approach was applicable to reducing the amount of pesticides during UAV spraying, which can provide a reference for precision agriculture aviation in the future.
ISSN:1934-6344
1934-6352
DOI:10.25165/j.ijabe.20191203.4358