基于智能手机的玉米冠层叶面积指数测定

doi:10.16843/j.sswc.2021.06.016

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摘要作物冠层在降雨分配与水土保持中具有重要作用，叶面积指数（leaf area index，LAI）是常见的作物冠层量化指数。本研究根据玉米冠层特征，模拟不同生育期（拔节期、小喇叭期、大喇叭期、抽穗期和成熟期）玉米植株冠层模型，通过手机图像获取，冠层阴影面积提取及修正、模型构建与验证等流程进行玉米冠层LAI的测定实验。试验包括3个太阳高度角（30°、60°和90°），玉米株数分别为1、2、3、6和9株，以代表不同采样面积，株行距为30 cm×50 cm。结果表明：笔者设计的LAI测定方法可行，即通过提取智能手机拍摄照片的阴影面积可测定冠层LAI（R²=0.96）。该方法简化了玉米冠层叶面积测量方法，为田间冠层参数的监测提供便捷的解决方案。

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	尹晓爱
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关键词 ：叶面积指数(LAI), 冠层结构, 测定方法, 玉米

Abstract：[Background] Crop canopy plays an important role on rainfall distribution and soil and water conservation, and leaf area index (LAI) is a common quantitative index of crop canopy. There are two kinds of direct method and indirect method in the current measurement of plant leaf area. The direct method is time consuming and has poor repeatability, while the indirect method is complicated and requires expensive equipment and is not convenient to be carried in field. Based on the existing problems of crop canopy measuring method, this study aims to explore a fast measurement method of maize LAI using the mobile phone. It provides scientific and technological conditions for further improving the method of determining canopy parameters by using smart phones and developing an effective mobile APP for canopy LAI measurement.[Methods] In this study, according to the characteristics of maize canopy, PVC pipe and simulated leaves were used to simulate the canopy model of maize plants at different growth stages (elongation period, small trumpet period, big trumpet period, tasseling period and mature period). The canopy LAI of maize was measured through the processes of mobile phone image acquisition, canopy shadow area extraction and correction, model construction and verification. The experiment included 3 solar altitude (30°, 60° and 90°). The number of maize plants was 1, 2, 3, 6 and 9 plants respectively to represent different sampling areas. The plant row spacing was 30 cm×50 cm.[Results] There was a significant correlation between the number of planted plants and the projected canopy area (P<0.05). There was no significant relationship between the solar altitude and the projected area taken by mobile phones (P>0.05), the canopy projection areas (S_M) extracted from mobile phone images was taken as the independent variable, and the canopy projection area (S_C) drawn on coordinate paper was taken as the dependent variable. The optimal fitting equation of the two was as follows:S_C=-0.009 6S²_M+171.38S_M-3 612.3 (R²=0.98). The fitting degree of this equation was high and reached significant level (P<0.05). There was a power function relationship between the projected area (S_C) drawn by coordinate paper and the actual area (S_leaf), and the function relationship was as follows:S_leaf=0.141 2S^0.985_C(R²=0.97), P<0.05, the regression equation had a high degree of fitting.[Conculsions] The LAI measurement method designed in this paper is feasible, that is, the canopy LAI could be accurately determined by extracting the shadow area taken by smart phones (R²=0.96). This method simplifies the canopy area measurement of maize and provides a convenient solution for the monitoring of canopy parameters in the field.

Key words： leaf area index(LAI) canopy structure determination method maize

收稿日期: 2020-10-26

PACS:

TP391.41

基金资助:贵州省科技计划项目"喀斯特高原山地典型植物冠层结构特征及定量化研究"（黔科合基础[217]1041）；贵州省科技拔尖人才项目"生物炭施用对岩溶山地水土流失与农业面源污染的阻控机制及效应研究"（黔教合KY字[2021]025）；中国博士后科学基金项目"石漠化区不同土岩镶嵌条件坡地土壤侵蚀机理研究"（2020M670527）

通讯作者: 侯瑞(1988-),女,博士,副教授。主要研究方向:森林保护与生态环境。E-mail:jiayouhourui123@163.com E-mail: jiayouhourui123@163.com

作者简介: 尹晓爱(1994-),女,博士研究生。主要研究方向:土壤侵蚀机理与土壤生态环境。E-mail:18224844759@163.com

引用本文:

尹晓爱, 杨秀超, 侯瑞, 赵龙山, 张金鑫. 基于智能手机的玉米冠层叶面积指数测定[J]. 中国水土保持科学, 2021, 19(6): 125-130.
YIN Xiaoai, YANG Xiuchao, HOU Rui, ZHAO Longshan, ZHANG Jinxin. Determination of canopy leaf area index of maize based on smart phone. SSWC, 2021, 19(6): 125-130.

链接本文:

http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2021.06.016 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2021/V19/I6/125

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