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Acta Agronomica Sinica ›› 2020, Vol. 46 ›› Issue (4): 557-570.doi: 10.3724/SP.J.1006.2020.94045

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Estimation of total nitrogen content in sugarbeet leaves under drip irrigation based on hyperspectral characteristic parameters and vegetation index

LI Zong-Fei1,SU Ji-Xia1,FEI Cong1,LI Yang-Yang1,LIU Ning-Ning1,DAI Yu-Xiang1,ZHANG Kai-Xiang1,WANG Kai-Yong1,FAN Hua1,*(),CHEN Bing2,*()   

  1. 1 Agronomy College, Shihezi University, Shihezi 832003, Xinjiang, China
    2 Cotton Institute, Xinjiang Academy of Agricultural and Reclamation Science, Shihezi 832003, Xinjiang, China
  • Received:2019-03-20 Accepted:2019-12-26 Online:2020-04-12 Published:2020-01-17
  • Contact: Hua FAN,Bing CHEN E-mail:fanhua@shzu.edu.cn;zyrcb@126.com
  • Supported by:
    This study was supported by the National Natural Science Foundation of China(31660360);This study was supported by the National Natural Science Foundation of China(31771720);the Research and Innovation Projects of Postgraduates in Autonomous Region(XJGRI2016039);the International Science and Technology Cooperation Promotion Plan of Shihezi University(GJHZ201706)

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Abstract:

The purpose of this paper is to clarify the quantitative relationship between total nitrogen content of sugar beet and high-resolution vegetation remote sensing, to explore the establishment of an optimal estimation model for total nitrogen content of sugar beet, and to monitor the growth of sugar beet. Xinjiang drip-irrigated sugar beet (Beta356) was selected to collect the reflectance spectra of leaf cluster during the leaves rapid growth period, root expansion period and sugar accumulation period by the ASD field hyperspectral apparatus. The total nitrogen content was also measured and the relationship between original spectral reflectance and total nitrogen content was analyzed. According to the correlation between the first-order differential spectral reflectance and total nitrogen content, a total nitrogen content estimation model was established. The model with spectral characteristic parameter Dr762 power function had a good ability to estimate total nitrogen content in leaves of beet, with the determination coefficient, relative error, and root mean square error of 0.747, 21.635, and 4.914, respectively. Various function estimation models were established based on vegetation index and leaf total nitrogen content. The linear function under vegetation index Dr762-Dr496 had better ability to estimate leaf total nitrogen content. Its determinant coefficient, relative error, and root mean square error were 0.794, 23.008, and 5.372, respectively.

Key words: total nitrogen, hyperspectral, characteristic parameters, vegetation index, estimation model

Table 1

Hyperspectral parameters and their definitions"

光谱特征参数与植被指数
Spectral characteristic parameter and Spectral index		 定义
Definition
红边斜率
Red edge slope (Dr)		 680-760 nm内最大一阶微分光谱值
Maximum first order differential spectrum in 680-760 nm
红边位置
Red edge position (λr)		 680-760 nm内最大的一阶微分光谱值对应的波长
The wavelength corresponding to the largest first-order differential spectrum in 680-760 nm
红边面积
Red edge area (SDr)		 680-760 nm内一阶微分光谱值的总和
The sum of the first-order differential spectral values in 680-760 nm
黄边斜率
Yellow edge slope (Dy)		 560-640 nm内最大一阶微分光谱值
Maximum first order differential spectrum in 560-640 nm
黄边位置
Yellow edge position (Λy)		 560-640 nm内最大一阶微分光谱值对应的波长
The wavelength corresponding to the largest first-order differential spectrum in 560-640 nm
黄边面积
Yellow edge area (SDy)		 560-640 nm内一阶微分光谱值的总和
The sum of the first-order differential spectral values in 560-640 nm
蓝边斜率
Blue edge slope (Db)		 490-530 nm内最大一阶微分光谱值
Maximum first order differential spectrum in 490-530 nm
蓝边位置
Blue edge position (λb)		 490-530 nm内最大一阶微分光谱值对应的波长
The wavelength corresponding to the largest first-order differential spectrum in 490-530 nm
蓝边面积
Blue edge area (SDb)		 490-530 nm内一阶微分光谱值的总和
The sum of the first-order differential spectral values in 490-530 nm
比值植被指数
Ratio vegetation index (RVI)		 Rλ1/Rλ2
差值植被指数
Difference vegetation index (DVI)		 Rλ1- Rλ2
归一化比值植被指数
Normalized ratio vegetation index (NDVI)		 (RNIR-Rred)/(RNIR+Rred)
红边归一化差异指数
Red edge normalized difference index (NDI)		 (DRλ1-DRλ2)/(DRλ1+DRλ2)

Fig. 1

Canopy hyperspectral reflectance and red edge at different nitrogen levels N0: nitrogen application of 0 kg hm-2; N75: nitrogen application of 75 kg hm-2; N150: nitrogen application of 150 kg hm-2; N225: nitrogen application of 225 kg hm-2."

Fig. 2

Correlation between original spectral reflectance and total nitrogen content in sugar beet canopy F0.05: significant correlation (P < 0.05); F0.01: extremely significant correlation (P < 0.01)."

Fig. 3

Correlation between the first derivative spectra of sugar beet canopy and the total nitrogen content F0.05: significant correlation (P < 0.05); F0.01: extremely significant correlation (P < 0.01)."

Table 2

Correlation between spectral characteristic parameters and vegetation index in sensitive bands and total nitrogen content"

光谱特征参数
Spectral characteristic parameter		 相关关系
Correlation		 植被指数
Vegetation index		 相关性Correlation
Dr 0.590** 原始光谱比值植被指数Ratio vegetation index R1104/R767 0.358**
λr 0.497** 原始光谱差值植被指数Difference vegetation index R1104-R767 0.280**
SDr 0.601** 原始光谱归一化植被指数Normalized ratio vegetation index (R1104-R767)/(R1104+R767) 0.364**
Dy 0.074 原始光谱比值植被指数Ratio vegetation index R767/R604 0.652**
Λy 0.089 原始光谱差值植被指数Difference vegetation index R767-R604 0.433**
SDy -0.086 一阶微分比值植被指数Ratio vegetation index Dr1138/Dr762 -0.169
Db 0.072 一阶微分差值植被指数Difference vegetation index Dr1138-Dr762 -0.744**
λb 0.506** 一阶微分归一化植被指Normalized ratio vegetation index (Dr1138-Dr762)/(Dr1138+Dr762) 0.500**
SDb -0.216 一阶微分比值植被指数Ratio vegetation index Dr762/Dr496 0.586**
R604 -0.267** 一阶微分差值植被指数Difference vegetation index Dr762-Dr496 0.721**
R1104 0.680** 红边比值植被指数Red edge ratio vegetation index Dr747/Dr687 0.431**
Dr1138 -0.715** 红边差值植被指数Red edge difference vegetation index Dr747-Dr687 0.589**
Dr762 0.703** 红边归一化差异指数Red edge normalized difference index (Dr747-Dr687)/( Dr747+Dr687) 0.545**

Table 3

Correlation between known hyperspectral vegetation index and total nitrogen content"

植被指数
Vegetation index		 计算公式
Calculation formula		 相关关系Correlation 文献来源
Source of literature
RSI R990/R720 0.528** [23]
NDSI (R860-R720)/(R860+R720) 0.582** [23]
NDVI (R790-R670)/(R790+R670) 0.332** [24]
FD-NDVI (R730-R525)/(R730+R525) 0.451** [25]
RENDVI (R750-R705/( R750+ R705) 0.367** [26]
mND705 (R750-R705)/(R750+2R445) 0.360** [27]
GNDVI (R790-R550)/(R790+R550) 0.464** [28]
SAVI 1.5(R870-R680)/(R870+R680+0.5) 0.692** [29]
OSAVI (1+0.16)(R810-R680)/(R810-R680+0.16) 0.633** [30]
MSAVI 0.5{2R800+1-[(2R800+1)2-8(R800-R670)]0.5} 0.623** [31]
DCNI (R720-R700/(R700-R670)/(R720-R670+0.03) 0.460** [32]
CIgreen [(R840-R870)/R550]-1 -0.493** [33]
NINI [lg(1/R1510)-lg(1/R1680)]/[lg(1/R1510)+lg(1/R1680)] 0.553** [34]
TVI 0.5[120(R750-R550)-200(R670-R550)] 0.538** [35]
DSI R800-R680 0.510** [36]

Table 4

Regression relationship model and verification of different spectral characteristic parameters and total nitrogen content"

高光谱特征参数
Characteristic parameter		 拟合模型 Fitting model 验证模型 Performance model
拟合方程 Equation R2 RE(%) RMSE
R1104 y = 63.88x-8.167 0.516 21.429 4.762
y = -30.27x2+96.39-16.64 0.519 22.299 4.829
y = 58.24x1.296 0.513 20.898 4.766
y = 7.555e2.277x 0.493 22.904 4.898
Dr1138 y = 64.73x-1.144 0.643 19.893 4.874
y = -47.08x2+104.7x-9.162 0.648 20.625 4.945
y = 63.68x1.031 0.643 19.909 4.881
y = 9.629e2.313x 0.615 23.265 5.010
Dr762 y = 157.8x-147 0.770 20.877 5.038
y = -192.3x2+578.8x-377.1 0.772 21.518 5.137
y = 13.96x6.461 0.747 21.635 4.914
y = 0.04302e5.813x 0.740 22.103 4.928

Fig. 4

Verification of the total nitrogen content estimation model under the spectral characteristic parameters Dr762 (maximum positive correlation of first order differential) of sugar beet"

Table 5

Regression model and verification of different vegetation indexes and total nitrogen content"

高光谱特征参数
Characteristic parameter		 拟合模型 Fitting model 验证模型 Performance model
拟合方程 Equation R2 RE(%) RMSE
SAVI y = 114.7x-105.7 0.541 24.492 5.092
y = 104.5x2-122.1x+28.18 0.544 23.153 4.926
y = 12.39x5.208 0.539 21.878 4.830
y = 0.1489e4.474x 0.535 21.514 4.829
Dr1138-Dr762 y = 49.36x+0.4913 0.732 19.708 4.709
y = -1.864x2+51.27x+0.04145 0.732 19.777 4.721
y = 49.73x0.9814 0.732 19.746 4.715
y = 9.737e1.842x 0.714 20.934 4.656
Dr762-Dr496 y = 12.85x+5.673 0.794 23.008 5.372
y = -2.828x2+21.68x-0.3212 0.804 22.996 5.608
y = 18.64x0.755 0.799 23.025 5.447
y = 11.91e0.4736x 0.759 24.623 5.288

Fig. 5

Validation of the estimation model of total nitrogen content under vegetation index Dr1138-Dr762"

Fig. 6

Validation of the estimation model of total nitrogen content under vegetation index Dr762-Dr496"

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