Abstract
Leaf coverage is an indicator of plant growth rate and predicted yield, and thus it is crucial to plant-breeding research. Robust image segmentation of leaf coverage from remote-sensing images acquired by unmanned aerial vehicles (UAVs) in varying environments can be directly used for large-scale coverage estimation, and is a key component of high-throughput field phenotyping. We thus propose an image-segmentation method based on machine learning to extract relatively accurate coverage information from the orthophoto generated after preprocessing. The image analysis pipeline, including dataset augmenting, removing background, classifier training and noise reduction, generates a set of binary masks to obtain leaf coverage from the image. We compare the proposed method with three conventional methods (Hue-Saturation-Value, edge-detection-based algorithm, random forest) and a frontier deep-learning method called DeepLabv3+. The proposed method improves indicators such as Qseg, Sr, Es and mIOU by 15% to 30%. The experimental results show that this approach is less limited by radiation conditions, and that the protocol can easily be implemented for extensive sampling at low cost. As a result, with the proposed method, we recommend using red-green-blue (RGB)-based technology in addition to conventional equipment for acquiring the leaf coverage of agricultural crops.
Highlights
Plant phenotyping is an important tool for linking environmental and genetic research, and is used to evaluate drought and climate-change resistance by comparing the growth differences between plant varieties [1]
This section compares the performance of the random forest (RF)-based image segmentation method with the performance of three other conventional segmentation methods: HSV segmentation based on color thresholding, edge detection-based image segmentation, and the convolutional neural network model called “DeepLabv3+” (Table 3)
A custom training and validation image dataset captured by using a unmanned aerial vehicles (UAVs) remote-sensing platform was preprocessed through a standardization dataset captured by using a UAV remote-sensing platform was preprocessed through a procedure
Summary
Plant phenotyping is an important tool for linking environmental and genetic research, and is used to evaluate drought and climate-change resistance by comparing the growth differences between plant varieties [1]. The study of leaf coverage evolved away from the general use of potted plants as research objects [3]. This done by by using the improved self-adaption. The principle of this algorithm using the improved self-adaption K-means clustering algorithm. The principle of this algorithm is is to to minimize the sum of the squares of the distance from each point in the cluster domain to the center of minimize the sum of the squares of the distance from each point in the cluster domain to the center the cluster [18]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
