基于高光谱遥感的冬小麦涝渍胁迫识别及程度判别分析

doi:10.12133/j.smartag.2021.3.2.202105-SA001

Smart Agriculture ›› 2021, Vol. 3 ›› Issue (2): 35-44.doi: 10.12133/j.smartag.2021.3.2.202105-SA001

• 专题--空间信息技术农业应用 • 上一篇下一篇

基于高光谱遥感的冬小麦涝渍胁迫识别及程度判别分析

杨菲菲(), 刘升平, 诸叶平, 李世娟()

中国农业科学院农业信息研究所/农业农村部信息服务技术重点实验室，北京 100081

收稿日期:2021-05-08 修回日期:2021-06-27 出版日期:2021-06-30 发布日期:2021-08-25
基金资助:
国家重点研发计划项目(2016YFD0200600);国家重点研发计划课题(2016YFD0200601);河北省重点研发计划项目(19227407D);中央级公益性科研院所基本科研业务费专项(Y2021XK09)
作者简介:杨菲菲（1995－），女，博士研究生，研究方向为农业信息技术。 E-mail：yangfeifei61@163.com。
通讯作者: 李世娟 E-mail:yangfeifei61@163.com;lishijuan@caas.cn

Identification and Level Discrimination of Waterlogging Stress in Winter Wheat Using Hyperspectral Remote Sensing

YANG Feifei(), LIU Shengping, ZHU Yeping, LI Shijuan()

Agricultural Information Institute, Chinese Academy of Agricultural Sciences/Key Laboratory of Agri-information Service Technology, Ministry of Agriculture and Rural Affairs, Beijing 100081, China

Received:2021-05-08 Revised:2021-06-27 Online:2021-06-30 Published:2021-08-25
corresponding author: Shijuan LI E-mail:yangfeifei61@163.com;lishijuan@caas.cn

摘要/Abstract

摘要：

冬小麦涝渍胁迫频发不仅严重影响区域粮食安全和生态安全，还威胁社会经济稳定和可持续发展。为识别冬小麦涝渍胁迫及判别其胁迫程度，本研究设置冬小麦涝渍胁迫梯度盆栽试验，采用ASD地物光谱仪和Gaiasky-mini2推扫式成像光谱仪分别测定叶片及冠层高光谱数据，结合植被指数、归一化均值距离和光谱微分差信息熵等方法，监测冬小麦是否遭受涝渍胁迫并判别其涝渍胁迫程度。试验结果显示，简单比值色素指数SRPI是识别涝渍胁迫冬小麦的最优植被指数。红光吸收谷（RW：640~680 nm）是识别冬小麦涝渍胁迫程度的最优波段，在RW波段内，抽穗、开花和灌浆期的光谱微分差信息熵可判别冬小麦涝渍胁迫程度，胁迫程度越大，光谱微分差信息熵越大。本研究为涝渍胁迫监测提供了一种新方法，在涝渍胁迫精确防控中具有较好的应用前景。

关键词: 高光谱遥感, 涝渍胁迫, 植被指数, 光谱微分差信息熵, 冬小麦

Abstract:

The frequent occurrence of waterlogging stress in winter wheat not only seriously affects regional food security and ecological security, but also threatens social and economic stability and sustainable development. In order to identify the waterlogging stress level of winter wheat, a waterlogging stress gradient pot experiment was set up in this research. Three factors were controlled: waterlogging stress level (control, slight waterlogging, severe waterlogging), stress duration (5 days, 10 days, 15 days) and wheat variety (YF4, JM31, JM38). Leaf and canopy hyperspectral data were measured by using ASD Field Spec3 and Gaiasky-mini2 imaging spectrometer, respectively. The data were collected from the first waterlogging day of winter wheat. The sunny and windless weather was selected and measured every 7 days until the wheat was mature. Combined with vegetation index, normalized mean distance and spectral derivative difference entropy, if winter wheat was under waterlogging stress was monitored and stress level was identified. The results showed that: 1) the spectral response characteristics of winter wheat under waterlogging stress changed significantly in RW, RE, NIR and 1650－1800 nm region, which may be due to the sensitivity of these regions to physiological parameters affecting the spectral response characteristics, such as pigment, nutrient, leaf internal structure, etc; 2) the simple ratio pigment index SRPI was the optimal vegetation index for identifying the waterlogging stress of winter wheat. The excellent performance of this vegetation index may come from its extreme sensitivity to the epoxidation state and photosynthetic efficiency of the xanthophyll cycle pigment; 3) the red light absorption valley (RW: 640－680 nm) region was the optimal region for identifying waterlogging stress level. In RW region, waterlogging stress level of winter wheat could be determined by the spectral derivative difference entropy at heading, flowering and filling stages. The greater the level of waterlogging stress, the greater the spectral derivative difference entropy. This may be due to the fact that the RW region was more sensitive to pigment content, and the spectral derivative difference entropy could reduce the effects of spectral noise and background. This study could provide a new method for monitoring waterlogging stress, and would have a good application prospect in the precise prevention and control of waterlogging stress. There are still shortcomings in this study, such as the difference between the pot experiment and the actual field environment, the lack of independent experimental verification, etc. Next research could add pot and field experiments, combine with cross-validation, to further verify the feasibility of this research method.

Key words: hyperspectral remote sensing, waterlogging stress, vegetation index, spectral derivative difference entropy, winter wheat

中图分类号:

S127

杨菲菲, 刘升平, 诸叶平, 李世娟. 基于高光谱遥感的冬小麦涝渍胁迫识别及程度判别分析[J]. 智慧农业(中英文), 2021, 3(2): 35-44.

YANG Feifei, LIU Shengping, ZHU Yeping, LI Shijuan. Identification and Level Discrimination of Waterlogging Stress in Winter Wheat Using Hyperspectral Remote Sensing[J]. Smart Agriculture, 2021, 3(2): 35-44.

图/表 7

图1

表1

植被指数列表

植被指数		定义描述
归一化植被指数^［20］（Normalized Difference Vegetation Index，NDVI）		$N D V I = (I R - R) / (I R + R)$ （1）
结构不敏感色素指数^［21］（Structure Insensitive Pigment Index，SIPI）		SIPI =（R₈₀₀-R₄₄₅）/（R₈₀₀+R₆₈₀）（2）
归一化植被水指数^［22］（Normalized Difference Water Index，NDWI）		$N D W I = (I R - M R) / (I R + M R)$ （3）
绿通道植被指数^［23］（Green Normalized Difference Vegetation Index，GNDVI）		GNDVI =（R₇₅₀-R₅₅₀）/ （R₇₅₀+R₅₅₀）（4）
光化学反射植被指数^［24］（Photochemical reflectance index， PRI）		$P R I = (R 531 - R 570) / (R 531 + R 570)$ （5）
简单比值色素指数^［25］（Simple Ratio Pigment Index，SRPI）		SRPI=R₄₃₀/R₆₈₀ （6）

表1

图2

图3

表2

图4

表3

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生育期	日期	PRI	SRPI
拔节期	3/15	0.28	0.11
拔节期	3/22	0.55	4.59
拔节期	3/30	1.76	4.01
抽穗期	4/08	1.62	1.68
开花期	4/16	4.26	4.58
灌浆期	4/24	3.55	7.79
成熟期	5/05	2.19	1.70

波段范围	ML5d	ML10d	ML15d	SL5d	SL10d	SL15d
RW	0.677	0.703	0.756	0.708	0.880	1.023
RE	1.161	1.212	1.165	1.234	1.093	1.092
NIR	1.298	1.175	1.215	1.300	1.232	1.213

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基于高光谱遥感的冬小麦涝渍胁迫识别及程度判别分析

Identification and Level Discrimination of Waterlogging Stress in Winter Wheat Using Hyperspectral Remote Sensing

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基于高光谱遥感的冬小麦涝渍胁迫识别及程度判别分析

Identification and Level Discrimination of Waterlogging Stress in Winter Wheat Using Hyperspectral Remote Sensing

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