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利用无人机遥感影像时间序列和品种性状对玉米株高模式进行模糊聚类

Fuzzy Clustering of Maize Plant-Height Patterns Using Time Series of UAV Remote-Sensing Images and Variety Traits.

作者信息

Han Liang, Yang Guijun, Dai Huayang, Yang Hao, Xu Bo, Feng Haikuan, Li Zhenhai, Yang Xiaodong

机构信息

College of Architecture and Geomatics Engineering, Shanxi Datong University, Datong, China.

Key Laboratory of Quantitative Remote Sensing in Agriculture of Ministry of Agriculture, Beijing Research Center for Information Technology in Agriculture, Beijing, China.

出版信息

Front Plant Sci. 2019 Jul 17;10:926. doi: 10.3389/fpls.2019.00926. eCollection 2019.

DOI:10.3389/fpls.2019.00926
PMID:31379905
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6652214/
Abstract

The application of high-throughput phenotyping (HTP) techniques based on unmanned aerial vehicle (UAV) remote-sensing platforms to study large-scale population breeding opens the way to more efficient acquisition of dynamic phenotypic traits and provides new tools that should help close the gap between genotyping and traditional field-phenotyping methods. Toward this end we used a field UAV-HTP platform to deploy a RGB high-resolution camera to acquire time-series images. By using three-dimensional reconstructed point cloud models, we developed a repeatable processing workflow to extract plant height from time-series images. The plant height determined by the UAV-HTP platform correlated strongly with that measured manually. The plant heights estimated at various growth stages form temporal profiles that give insights into changes and trends in genotyping. Based on fuzzy c-means clustering analysis, we extract the typical dynamic patterns in phenotypic traits (i.e., plant height, average rate of growth of plant height, and rate of contribution of plant height) hidden in the temporal profiles. The fuzzy c-means clustering and set-intersection operation were first applied to analyze the temporal profile to identify how plant-height patterns change and to detect differences in phenotypic variability among the genotypes. The results revealed the capacity of UAV remote sensing to easily evaluate field traits on multiple timescales, for a few breeding plots or for 1000s of breeding plots.

摘要

基于无人机(UAV)遥感平台的高通量表型分析(HTP)技术在大规模群体育种研究中的应用,为更高效地获取动态表型性状开辟了道路,并提供了新工具,有望缩小基因分型与传统田间表型分析方法之间的差距。为此,我们使用了一个田间无人机-高通量表型分析平台,搭载RGB高分辨率相机来获取时间序列图像。通过使用三维重建点云模型,我们开发了一种可重复的处理流程,从时间序列图像中提取株高。无人机-高通量表型分析平台测定的株高与人工测量的株高高度相关。在各个生长阶段估算的株高形成了时间剖面,有助于洞察基因分型中的变化和趋势。基于模糊c均值聚类分析,我们从时间剖面中提取了表型性状(即株高、株高平均生长速率和株高贡献率)中隐藏的典型动态模式。首次应用模糊c均值聚类和集合交集运算来分析时间剖面,以确定株高模式如何变化,并检测不同基因型之间表型变异性的差异。结果表明,无人机遥感能够轻松地在多个时间尺度上评估少数育种小区或数千个育种小区的田间性状。

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