Establishing NDRE dynamic models of winter wheat under multi-nitrogen rates based on a field spectral sensor

Meiyan Shu; Meiyan Shu; Meiyan Shu; Meiyan Shu; Xiaohe Gu; Xiaohe Gu; Longfei Zhou; Longfei Zhou; Longfei Zhou; Bo Xu; Bo Xu; Bo Xu; Guijun Yang; Guijun Yang; Guijun Yang

doi:10.1364/AO.410470

Applied Optics
Vol. 60,
Issue 4,
pp. 993-1002
(2021)
•https://doi.org/10.1364/AO.410470

Establishing NDRE dynamic models of winter wheat under multi-nitrogen rates based on a field spectral sensor

Meiyan Shu, Xiaohe Gu, Longfei Zhou, Bo Xu, and Guijun Yang

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Meiyan Shu, Xiaohe Gu, Longfei Zhou, Bo Xu, and Guijun Yang, "Establishing NDRE dynamic models of winter wheat under multi-nitrogen rates based on a field spectral sensor," Appl. Opt. 60, 993-1002 (2021)

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Abstract

Field spectral sensors provide real-time, reliable, quantitative monitoring of crop growth. Fitting the continuous growth in the entire growing period from the measurements of limited frequency is helpful to the comparative analysis of interannual growth and fertilizer management in the field. To exploit this capacity, our work presents a model that uses the normalized difference red edge (NDRE) index derived from the field spectral sensor for real-time monitoring of the canopy growth of winter wheat in the whole growing period. We developed this model from experiments in three counties in Hebei province, China, where we obtained the near-infrared and red edge reflectance, grain yield, and canopy parameters for eight growth stages and for various nitrogen (${\rm N}$) rates. Given the correlation between effective accumulated temperature and crop growth, we used the growing degree-days as an adjustment parameter to develop models for dynamic monitoring of the NDRE of the winter wheat canopy during the entire growing period. The results show that high determination coefficients (${{\rm R}^2} = {0.89}$ to 0.96) are obtained from all models based on relative NDRE and effective accumulative temperature (independent of ${\rm N}$ fertilization rates). The model based on the rational function is the best of all models tested, with the accuracy for normal and high ${\rm N}$ fertilization rates being slightly greater than that for low ${\rm N}$ fertilization rates. Therefore, a relative-NDRE model with the accumulative growing degree-days since sowing could allow monitoring canopy NDRE of winter wheat at any time, which could be helpful for overcoming the shortage of incomparable growth derived from the differences of sensing date, sowing date, and fertilizer, etc.

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Experiment	Location	Cultivar	$N$ Rate (kg/ha)	Seeding Date (Month/Day)	Measuring Date (Month/Day)
1	Gaocheng	Shimai18, Gaoyou2018	105, 210, 420	10/6	11/30, 3/6, 3/16, 3/26, 4/7, 4/17, 4/30, 5/20, 6/9
2	Jinzhou	Jimai22, Heng4399	105, 210, 420	10/10	11/25, 3/13, 3/28, 4/18, 4/30, 6/10
3	Luquan	Liangxing99, Jimai22	105, 210, 420	10/8	11/24, 3,14, 3/26, 4/14, 4/29, 6/11

$N$ Rates	Model	$a$	$b$	$c$	$d$	$R_{2}$	RMSE
$1 / 2 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ $y = {a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	6.468	0.363	−168.444	0.217	0.9488	0.058
		−1.668	13.642	−29.198	22.543	0.9481	0.059
		0.334	-1.498	−5.706	4.937	0.9551	0.0544
		−17.372	-2.146	−38.628	0.0199	0.9397	0.063
		0.91	25.2757	9.147	0	0.9258	0.07
$1 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ ${y = a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	6.601	0.323	−1967.97	0.227	0.93	0.067
		−1.3199	11.5784	−24.6094	19.264	0.9008	0.08
		0.338	−1.49	−5.505	4.741	0.939	0.063
		−2.891	−1.004	−2.908	0.0009	0.894	0.083
		1.057	13.325	7.111	0	0.886	0.086
$2 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ ${y = a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	8.362	0.331	42.88	3.941	0.889	0.087
		−1.3659	11.8005	−24.3965	18.6031	0.9032	0.082
		0.362	−1.596	−5.477	4.624	0.9495	0.0589
		−13.728	−1.592	−22.606	0.017	0.898	0.084
		1.018	15.2397	8.078	0	0.889	0.087

Nitrogen Levels	Luquan $R^{2}$	Luquan RMSE	Jinzhou $R^{2}$	Jinzhou RMSE
$1 / 2 N$	0.659	0.234	0.6	0.414
$1 N$	0.86	0.084	0.914	0.1
$2 N$	0.812	0.085	0.921	0.085

Experiment	Location	Cultivar	$N$ Rate (kg/ha)	Seeding Date (Month/Day)	Measuring Date (Month/Day)
1	Gaocheng	Shimai18, Gaoyou2018	105, 210, 420	10/6	11/30, 3/6, 3/16, 3/26, 4/7, 4/17, 4/30, 5/20, 6/9
2	Jinzhou	Jimai22, Heng4399	105, 210, 420	10/10	11/25, 3/13, 3/28, 4/18, 4/30, 6/10
3	Luquan	Liangxing99, Jimai22	105, 210, 420	10/8	11/24, 3,14, 3/26, 4/14, 4/29, 6/11

$N$ Rates	Model	$a$	$b$	$c$	$d$	$R_{2}$	RMSE
$1 / 2 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ $y = {a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	6.468	0.363	−168.444	0.217	0.9488	0.058
		−1.668	13.642	−29.198	22.543	0.9481	0.059
		0.334	-1.498	−5.706	4.937	0.9551	0.0544
		−17.372	-2.146	−38.628	0.0199	0.9397	0.063
		0.91	25.2757	9.147	0	0.9258	0.07
$1 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ ${y = a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	6.601	0.323	−1967.97	0.227	0.93	0.067
		−1.3199	11.5784	−24.6094	19.264	0.9008	0.08
		0.338	−1.49	−5.505	4.741	0.939	0.063
		−2.891	−1.004	−2.908	0.0009	0.894	0.083
		1.057	13.325	7.111	0	0.886	0.086
$2 N$	$y = (1 + \exp (- a * (x - b)))^{(- 1)} - (1 + \exp (- c * (x - d)))^{(- 1)}$ ${y = a + b * x + c * x}^{2} + {d * x}^{3}$ $y = (a + b * x) / ({c * x + d * x}^{2} + 1)$ $y = ({a * b + c * x}^{d}) / ({b + x}^{d})$ $y = a / (1 + b * \exp (- c * x))$	8.362	0.331	42.88	3.941	0.889	0.087
		−1.3659	11.8005	−24.3965	18.6031	0.9032	0.082
		0.362	−1.596	−5.477	4.624	0.9495	0.0589
		−13.728	−1.592	−22.606	0.017	0.898	0.084
		1.018	15.2397	8.078	0	0.889	0.087

Abstract

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Applied Optics