Abstract
As a plant organ with the largest surface area, leaves are the main place where photosynthesis and respiration take place. High-throughput phenotyping of crop leaves is of great significance for breeding, growth monitoring, and increasing crop yield. Due to the highly complex and diversified plant structures, automated leaf segmentation and phenotypic feature extraction remain to be challenging tasks. In this article, we propose a novel five-stage framework that comprises multiview stereo point cloud reconstruction, preprocessing, stems removal in canopy, leaf segmentation, and leaf phenotypic feature extraction to carry out leaf phenotyping on two types of ornamentals— Maranta arundinacea and Dieffenbachia picta . The phenotypic traits such as the leaf area, leaf length, width, and leaf inclination angle for each single leaf are calculated and compared with ground truths. The experimental results show that the average accuracy of calculated leaf area of the two species reached 96.8% and 97.8%, respectively. The average errors of both the calculated leaf length and width of Maranta arundinacea are less than 4.0%, and for Dieffenbachia picta , the average errors of calculated leaf length and width are both no higher than 4.7%. The average errors of calculated leaf inclination angle for the two plant species are 2.9° and 3.0°, respectively.
Highlights
P HENOTYPE is a group of biological traits that link the interaction between genotype and environment
After the feature extraction and matching by VisualSFM, two dense point cloud with 1 400 333 points and 770 037 points are constructed by clustering views for multiview stereo (CMVS), respectively
The Maranta arundinacea sample 1 has 688 374 points, and the sample 2 has 331 992 points, while 226 878 points remain in the Dieffenbachia picta sample 1, and 138 226 points remain in sample 2
Summary
P HENOTYPE is a group of biological traits that link the interaction between genotype and environment. Plant phenotypes intuitively reflect the growth state of plants, and observing the plant phenotypes is the basis of all breeding processes [1]. Plant phenotyping [2] is the comprehensive assessment of complex plant traits such as growth, development, tolerance, resistance, architecture, physiology, ecology, yield, and the basic measurement of individual quantitative parameters that form the basis for more complex traits. The quantitative analysis of plant phenotypes generally comprises the following aspects: Manuscript received February 29, 2020; revised March 26, 2020; accepted April 20, 2020. Date of publication April 27, 2020; date of current version May 29, 2020.
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