A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle
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Article

A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle

1
National Engineering and Technology Center for Information Agriculture, Nanjing Agricultural University, Nanjing 210095, China
2
Key Laboratory for Crop System Analysis and Decision Making, Ministry of Agriculture, Nanjing Agricultural University, Nanjing 210095, China
3
Jiangsu Key Laboratory for Information Agriculture, Nanjing Agricultural University, Nanjing 210095, China
4
Jiangsu Collaborative Innovation Center for Modern Crop Production, Nanjing Agricultural University, Nanjing 210095, China
*
Author to whom correspondence should be addressed.
Remote Sens. 2018, 10(12), 2026; https://doi.org/10.3390/rs10122026
Submission received: 1 November 2018 / Revised: 29 November 2018 / Accepted: 10 December 2018 / Published: 13 December 2018
(This article belongs to the Special Issue Remote Sensing for Precision Nitrogen Management)

Abstract

:
Unmanned aerial vehicle (UAV)-based remote sensing (RS) possesses the significant advantage of being able to efficiently collect images for precision agricultural applications. Although numerous methods have been proposed to monitor crop nitrogen (N) status in recent decades, just how to utilize an appropriate modeling algorithm to estimate crop leaf N content (LNC) remains poorly understood, especially based on UAV multispectral imagery. A comparative assessment of different modeling algorithms (i.e., simple and non-parametric modeling algorithms alongside the physical model retrieval method) for winter wheat LNC estimation is presented in this study. Experiments were conducted over two consecutive years and involved different winter wheat varieties, N rates, and planting densities. A five-band multispectral camera (i.e., 490 nm, 550 nm, 671 nm, 700 nm, and 800 nm) was mounted on a UAV to acquire canopy images across five critical growth stages. The results of this study showed that the best-performing vegetation index (VI) was the modified renormalized difference VI (RDVI), which had a determination coefficient (R2) of 0.73 and a root mean square error (RMSE) of 0.38. This method was also characterized by a high processing speed (0.03 s) for model calibration and validation. Among the 13 non-parametric modeling algorithms evaluated here, the random forest (RF) approach performed best, characterized by R2 and RMSE values of 0.79 and 0.33, respectively. This method also had the advantage of full optical spectrum utilization and enabled flexible, non-linear fitting with a fast processing speed (2.3 s). Compared to the other two methods assessed here, the use of a look up table (LUT)-based radiative transfer model (RTM) remained challenging with regard to LNC estimation because of low prediction accuracy (i.e., an R2 value of 0.62 and an RMSE value of 0.46) and slow processing speed. The RF approach is a fast and accurate technique for N estimation based on UAV multispectral imagery.

Graphical Abstract

1. Introduction

Nitrogen (N) is one of the most important nutrients required for plant growth and is therefore critical for crop production. A deficiency in N significantly reduces crop photosynthetic yields while the excessive use of fertilizers for this element leads to both resource waste and environmental pollution [1,2]. Furthermore, leaf N content (LNC) at early growth stages (e.g., jointing and booting) is a good indicator for N fertilizer application [3], and LNC at late growth stages (e.g., after heading) is highly related to the final grain quality [4]. Quantification of LNC is therefore a prerequisite for the production of high-yield and good-quality crops while causing minimal environmental impact.
Remote sensing (RS) has become an attractive technique in precision agricultural assessment as it can be used to monitor crop growth status rapidly and nondestructively. The main RS platforms currently in use include satellite, manned airborne, and ground-based approaches, which can all be equipped with various kinds of sensors. Although satellite images can be used to monitor N status across large areas [5,6], they cannot provide sufficient accuracy because of their low spatio-temporal resolution. Even though manned airborne platforms are able to capture images at high spatio-temporal resolution, this approach is limited by both high operational complexity and cost [7].
In contrast, ground-based RS platforms are able to attain high N status estimation monitoring accuracy [8,9], but this approach remains inefficient when used over large areas, while unmanned aerial vehicle (UAV)-based RS platforms provide a low-cost alternative for collecting RS data at high spatio-temporal resolution [10,11]. This platform has been widely applied in precision agriculture and has been utilized for LAI [12] as well as biomass estimations [10,13], but few studies to date have discussed N status detection using this approach [14,15]. It therefore remains an open question whether, or not, UAV images can be used to monitor N status.
A range of methods have so far been proposed that use spectral data to model N content, including statistical and chemometric algorithms alongside physical models. The statistical method has been used most commonly to monitor N content based on optical measurements from different platforms [8,16]. Empirical relationships between LNC and canopy optical properties have also been calibrated using experimental datasets, an approach that has proven to be both efficient and accurate [8,9,17]. It is also the case, however, that retrieval algorithms based on vegetation indices (VIs) tend to exhibit poor model portability because they are easily influenced by band configuration, index formulation, and fitting function [18]. Besides, most VIs are easily saturated at high N content levels [8,19].
An additional set of techniques that have been commonly applied to identify variables for N modeling comprise non-parametric algorithms, including partial least square regression (PLSR), artificial neural networks (ANNs), random forest (RF), and support vector machines (SVMs) [3,20,21]. These approaches make full use of all spectral data and avoid multicollinearity that is inherent to multiple linear regressions [20]. As these methods have also been shown to be very efficient for processing nonlinear data, it is likely that they are also able to deal with high-dimensional data [21] although performance remains an issue [22,23]. In the earlier study, Verrelst et al. [23] investigated the efficiency of four machine learning regression algorithms at estimating leaf chlorophyll content (LCC), LAI, and fractional vegetation cover (FVC), specifically neural networks (NN), support vector regression (SVR), kernel ridge regression (KRR), and Gaussian processes regression (GPR). As the results of this study showed that the latter was more efficient compared to the other three [23], it will also be worthwhile to investigate the performance of different non-parametric algorithms for LNC estimation.
It remains challenging to quantify LNC differences based on small-plot experiments using several cultivars as well as N application levels and planting densities. As differences in N content under experimental conditions are generally limited, established models might be unstable in practical applications. It is also the case that a significant component of variations in canopy optical properties are also due to changes in sun zenith angles, canopy structures, and background. As these differences significantly affect the relationships between spectral parameters and N content, a model based on physical parameters should enable us to clearly explain these potentially confounding factors. Although a PROSAIL radiative transfer model (RTM) [24] used in combination with hyperspectral reflectance has been shown to provide an effective method for estimating crop LAI [25,26] and LCC [27], it remains unclear how this approach can be utilized to offer enough LNC estimation accuracy with UAV multispectral imagery.
The different modeling algorithms discussed above were studied here using a range of species and sites. One key aim of this research was to comprehensively compare these approaches and determine the optimal retrieval method for a particular objective, especially when using UAV images. A range of questions remains to be addressed, including which VI is optimal for wheat LNC estimation? Which non-parametric algorithm provides the best estimates? How well do physical models perform for LNC retrieval when based on UAV multispectral images? Additionally, which is the best approach when all three modeling algorithms are compared in terms of processing efficiency, model simplification, and estimation accuracy? The objective of this study was therefore to evaluate the performance of these three different retrieval methods for winter wheat LNC estimation using UAV multispectral imagery.

2. Materials and Methods

2.1. Experimental Design

Three field experiments were conducted over two growing seasons (2013–2014 and 2014–2015) in Rugao City (120°45′E, 32°16′N) within Jiangsu Province in eastern China. The predominant soil type is loam and the soil organic matter was 18.9–24.6 g/kg, available N was 140.56–150.41 mg/kg, total nitrogen was 1.87–2.07 g/kg, available phosphorus was 50.12–57.84 mg/kg, and available potassium was 90.32–96.76 mg/kg. These experiments involved different N rates, planting densities, and wheat cultivars, and comprised a randomized complete block design with three replicates, thus there were 36, 30, and 36 treatments for Exp. 1, Exp. 2, and Exp. 3, respectively. A mixture of 120 kg/ha P2O5 and 120 kg/ha K2O was applied to all treatments prior to seeding. Crop management followed local standard practices for wheat production; additional details regarding these three experiments are provided in Table 1.

2.2. Data Collection

2.2.1. UAV System and Image Acquisition

An eight-rotor MK-Oktokopter UAV (Mikrokopter Inc., Moormerland, Germany) was used to carry a six-channel multispectral Tetracam mini-MCA6 camera (Tetracam Inc., Chatsworth, CA, USA) to collect images in this study (Figure 1). The specific parameters of this UAV and camera are shown in Table 2. This multispectral camera was equipped with five spectral channels (i.e., 490 nm, 550 nm, 671 nm, 700 nm, and 800 nm) with a 10 nm bandwidth, and had an incident light sensor (ILS). All UAV campaigns were undertaken in stable ambient light conditions (between 11:00 and 13:30) at five critical growth stages (Table 1). The UAV was flown at a height of 150 m, and images were collected with spatial resolution of 8.125 cm. After each flight, only one image with high quality was selected for image analysis due to the small study area (50 m × 35 m).

2.2.2. Ground Sampling

A total of 30 wheat plant samples were randomly collected from each plot subsequent to each UAV campaign in order to determine LNC values (%). All the green leaves from each sample were separated from stems, oven-dried at 80 °C to a constant weight, and then weighed. Dried leaf samples were ground to pass through a 1 mm screen and stored in plastic bags for subsequent chemical analysis. Total leaf N concentration was determined using the micro-Kjeldahl method. Leaf chlorophyll content (Cab) was measured using a soil and plant analyzer development (SPAD) 502 (Minolta Camera Co., Osaka, Japan) with sub-samples (five plants) randomly selected and the first, second, and third fully expanded leaves chosen from three layers encompassing the base, middle, and top parts of wheat leaves. Averaged SPAD readings were taken as sample values in each case. Absolute leaf chlorophyll content (LCC) was then obtained using an equation that expresses the relationship between SPAD readings and LCC values [28].

2.3. Image Processing

The pre-processing UAV image workflows used in this analysis followed those proposed by [12,29], and included noise reduction, veginetting, and lens distortion correction as well as band registration and radiometric calibration. Thirty ground control points (GCPs) were evenly distributed in the experimental area, and the geographic coordinates were determined by X900 GNSS (Huace Inc., Beijing, China). The GCPs were used for band registration and georeferencecing processed in the ENVI/IDL environment (Exelis Visual Information Solutions, Boulder, CO, USA). After that, radiometric calibration was conducted by the empirical line method [30] with four standard calibration canvas with different reflectance values (3%, 22%, 48%, and 82%). Reflectance was then extracted from each radiometrically corrected image using a region of interest (ROI) from each plot.

2.4. Retrieval Techniques

2.4.1. Parametric Modeling Algorithms

The parametric modeling algorithm used in this analysis was based on VI calculated with reflectance from UAV multispectral images. Thus, 19 kinds of VI formulations, including two-band, three-band, and four-band indices, encompassing all possible combinations were used to develop correlations versus wheat LNC (Table 3). Linear regression between LNC and all VIs was utilized to eliminate the impact of functions as opposed to band selection and index formulation.

2.4.2. Non-Parametric Modeling Algorithms

The SimpleR toolbox [45] was used in this study to implement 13 non-parametric modeling algorithms and to develop models. A comprehensive description of these algorithms was presented in [46]. These non-parametric approaches can be further subdivided into linear and non-linear regressions; of these, three fall into the former category-least-squares linear regression (LSLR), principal component regression (PCR), and partial least-squares regression (PLSR)-while 10 fall into the latter-artificial neutral networks (ANN), decision trees (DT), regression trees (RT), bagging trees (BaT), and boosting trees (BoT) as well as random forest (RF), relevance vector machine (RVM), kernel ridge (KRR), and Gaussian processes regressions (GPR) alongside variational heteroscedastic GPR (VH-GPR) and extreme learning machines (ELM).

2.4.3. Physical Based Modeling

The widely used PROSAIL radiative transfer model comprises a combination of the SAIL canopy reflectance and PROSPECT leaf optical properties models. The combined approach was utilized here to retrieve canopy parameter data and was generated via both the latter two methods, PROSPECT-5 and 4SAIL. A look-up-table (LUT) was then applied; these efficient inversion algorithms are commonly used for agronomic parameter retrieval [46,47]. The imposed boundaries and distributions of PROSAIL input variables used in this study are summarized in Table 4; these values were obtained from field measurements and other studies that have utilized the same crops [47,48]. Thus, uniform distributions of LCC and normally distributed LAI were sampled 100 times, uniform carotenoid distributions were sampled 50 times, and all other variables were held constant. A resultant LUT dataset comprising 500,000 parameter combinations was chosen for this analysis; a total of 22 cost functions, including the insertion of up to 50% Gaussian noise into simulated data and multiple best solutions, were considered to optimize the LUT inversion strategy to address radiative transfer model issues [49]. After LCC was retrieved from the PROSAIL model, LNC was indirectly obtained on the empirically linear relationship between LCC and LNC.

2.5. Model Calibration and Validation

Table 5 lists the calibration and validation of models on different methods. Data collected from all experiments were pooled to examine the relationship between VIs and LNC with linear regression, and then the optimal bands’ configurations were determined. Both the LNC-VI model and non-parametric model were calibrated and validated with a k-fold (k = 10) cross-validation procedure. The whole dataset was randomly divided into 10 equal-sized sub-datasets. Nine sub-datasets were used as the calibration (training) dataset and the rest was used as the validation (test) dataset, then this procedure was repeated 10 times [48]. For the physical-based modeling method, predicted LNC values, after being retrieved from the empirical model, were compared with the field measured values. The predictive capability of those models with different methods was then assessed using the determination coefficient (R2) and root mean square error (RMSE). All the above procedures were implemented using MATLAB 2014a (The MathWorks Inc., Natick, MA, USA).

3. Results

3.1. Optimal VI Determination

Relationships between LNC and 19 different formulas with random bands were established, and the best-performing VIs in each case are listed in Table 6. Results show that both RDVI and SAVI performed equally well in the case of two-band indices (R2 = 0.73 and RMSE = 0.38, respectively), outperforming other examples. In addition, optimal VI values for each formulation comprising two bands were constructed with a red edge (720 nm) and a near infrared band (800 nm); results show that EVI was superior to others in terms of LNC estimation in the case of three-band indices yielding an R2 and RMSE of 0.73 and 0.38, respectively. Data show that all four-band indices exhibited similar LNC estimation efficiency even when encompassing different band combinations, but performed worse than optimal two-band and three-band VI variations. It is also clear that formulation type exerts a significant influence on VI performance even when the same bands are employed. In addition, this modeling method is characterized with an extremely fast speed (within 0.05 s) under the MATLAB. From the scatter plots shown in Figure 2, the saturation at high LNC values still exists despite a relatively high R2, resulting in low estimation accuracy at high values.

3.2. Optimal Non-Parametric Modeling Algorithm Determination

A total of 13 non-parametric modeling algorithms were utilized in this study to estimate wheat LNC (Table 7); data show that all outperformed optimal VI, with the exception of RT. Indeed, the best-performing regression method was RF, which yielded an R2 of 0.79 and an RMSE of 0.33 and had a fast processing speed of 2.28 s. In addition, we found that the majority of nonlinear non-parametric modeling algorithms were superior to their linear counterparts. Albeit yielding accurate estimates, RVM, ELM, VH-GPR, and NN approaches all proceeded very slowly. In contrast, the linear non-parametric regression models of LSLR, PCR, and PLSR were all extremely fast, more rapid even than their parametric counterparts.
The data presented in Figure 3a comprise scatter plots of measured LNC values versus estimated ones derived from the optimal non-parametric RF algorithm. In this case, estimated values at the high level turned out to be closer to the 1:1 line than those generated from RDVI. Thus, after measuring the importance of predictor variables using the mean squared error (MSE) [50], it is clear that these values for NIR (800 nm) bands were the largest among the five, followed by the red (671 nm) band (Figure 3b). The red (671 nm) and NIR (800 nm) bands are therefore more important for LNC estimation than any of their counterparts.

3.3. Performance of LUT-Based PROSAIL Inversion Performance

The data presented in Table 8 illustrate the performance of the LUT-based PROSAIL model with different cost functions, noise proportions, and multiple solutions. In this case, however, as LNC could not be retrieved directly from the PROSAIL model, LCC was initially estimated. The optimal inversion strategy for LCC retrieval used in this study was K(x) = log(x)2 with R2 and RMSE values of 0.81 and 7.05, respectively. LNC was then indirectly estimated subsequent to LCC inversion via the relationship between LCC and LNC (Figure 4a). The PROSAIL model performance in LNC inversion was not particularly satisfactory with an R2 value of 0.62 (Figure 4b); thus, compared to both VIs and non-parameter modeling methods, the LUT-based PROSAIL approach actually performed worse although the processing speed in this case was comparable with those of non-linear non-parametric regression algorithms.

3.4. Effects of Growth Stage, Cultivar, and Cultivation Factors on Estimation Accuracy

The data presented in Table 9 summarize the effects of growth stage, cultivar, planting density, and year on the estimation accuracy of different methods. These records show that for different growth stages, both RDVI and LUT-based methods performed better in the middle of the season (i.e., booting, heading, and anthesis) compared to either early (i.e., jointing) or late (filling) stages. An RF approach was able to obtain accurate estimates from jointing to anthesis stages alongside lower ones at the filling stage.
The results of this study reveal varied RDVI performance depending on the wheat cultivar; the most accurate estimates were recovered for Ningmai 13 (RRMSE = 10.4%) while the worst were seen for Shenxuan 6 (RRMSE = 14.0%). The RF approach also generated satisfactory and stable values for different cultivars with RRMSE ranging between 10.7% and 12.0%, while the LUT-based retrieval method also performed equally in all cases.
As planting density increased, LNC estimation accuracy gradually decreased based on RDVI and the best performance was obtained at the lowest density. At the same time, the LUT-based retrieval method yielded highest accuracies at the lowest density while the RF approach led to comparable performance at different planting densities. All three methods performed better for 2014 than for 2015.

4. Discussion

Although ground-based spectral data and satellite images have been widely utilized to monitor the N status of crops [9,16,51], few studies to date have assessed the capabilities of UAV platforms. We evaluated the performance of UAV images using different modeling algorithms and demonstrate that this approach provides a reliable technique for winter wheat leaf N content estimation.
The results of this analysis show that in terms of parametric approaches, use of an RDVI modified with NIR and red edge bands provides optimal VI values for LNC estimation (i.e., R2 = 0.73; RMSE = 0.38); this result is in close agreement with the previous findings of Inoue et al. [20] and Yao et al. [52], who noted that a combination of NIR and red edge bands provides an efficient approach for N status monitoring. The RDVI is also advantageous because it optimizes the vegetation signal and therefore has an improved degree of sensitivity in high-biomass regions; this approach is able to enhance vegetation monitoring via decoupling of the canopy background signal and reducing atmospheric influence [38].
However, even though results of sufficient accuracy were obtained in this analysis using a simple model, a number of drawbacks remain, including the fact that this approach becomes saturated at high N rates and canopy densities; it is easily affected by the growth stage, and information is lost at other spectral bands. Indeed, the RDVI performed poorly at both jointing and filling stages (Table 8), a result that might be explained by the fact that the canopy was mixed with soil background during the early stage and then panicles later in development. Furthermore, the accuracy of estimation decreased from the booting to filling stage, which might be due to the differences of the leaf biomass at varied stages [53]. The use of the VI incorporating more bands was also unable to generate higher accuracy than a two-band approach; furthermore, different formulas with the same bands performed significantly in LNC estimation, which indicated that both band configuration and VI formulation played an important role in LNC estimation. It is also crucial to consider the applicability of VI-LNC models as the performance of these approaches often depends on the ecological site, crop type, and growth stage [54]. The RDVI-LNC model should therefore be tested using additional datasets so as to extend its capability in the future.
It is well known that vegetation canopy spectral signatures are dominated by numerous biophysical and biochemical variables [55,56]. Thus, compared with parametric methods, most non-parametric algorithms tend to perform better because this regression family makes full use of all spectral information and so are able to better handle confounding factors when compared to VI values [20,22]. Although linear non-parametric algorithms performed lightly worse than their nonlinear counterparts in this analysis, these approaches possessed an extremely fast processing speed; this attribute indicates that these methods comprise a promising technique that can be integrated into crop monitoring systems.
Previous studies have also shown that linear non-parametric algorithms, such as PLSR, are able to generate satisfactory estimates for crop biomass [3] as well as N [20] and chlorophyll content [22]. The results of this study show that amongst non-parametric algorithms, the RF approach was both the most accurate and stable method under different conditions because RF provides a nonlinear regression with LNC and has the advantage of dealing with a large dataset with high speed and efficiency [50,57]. Furthermore, RF also has the ability to rank the importance of variables [50,57]. We therefore recommend that the RF approach would be a reliable technique for crop N estimation, even though many software packages do not yet include this algorithm.
The LUT-based retrieval method used in this study had the lowest LNC estimation accuracy of the three approaches tried, in contrast to previous research results [27,58]. Indeed, as some variables (e.g., LAI and chlorophyll content) could be retrieved directly from the PROSAIL model while LNC was generated indirectly from the empirical relationship between LNC and LCC [59,60], estimation accuracy was influenced by retrieval equation accuracy. We also note that the LUT-based retrieval method has a number of drawbacks, including the need for too many input parameters, large data size, and long processing times, and the fact that only parameters inherent to the model can be retrieved. However, a physical model has the advantage of offering uncertainty estimates, which provide information on model transplantation possibilities.
Although previous studies have attempted to employ UAV-based images to monitor crop N status [14,15], the datasets used was small and so estimation accuracy was unsatisfactory. In contrast, the results of this study show that the RDVI generated higher estimates while the non-parametric RF regression method led to a higher degree of accuracy under different conditions. These results suggest that UAV-based multispectral images provide a promising approach that can be applied to crop N status monitoring. However, even though a high predictive accuracy was obtained in this study, the established LNC model will still need to be tested with data from other ecological sites and crop types as the variables used here came from just one site. We also show that the PROSAIL model is not suitable for LNC retrieval because of its low predictive accuracy unless the relationship between this variable and LNC can be made more robust.

5. Conclusions

A range of modeling algorithms (i.e., parametric, non-parametric, and physical retrieval) were employed in this study to estimate winter wheat LNC using UAV-based multispectral images. Estimation models were then cross-validated with datasets from different growing seasons, including different stages, cultivars, N rates, and planting densities. In terms of parametric regressions, modified RDVI with a red edge and NIR bands turned out to comprise the best-performing index with the most accurate cross-validated result (i.e., R2 = 0.73, RMSE = 0.38). This method was also characterized by an extremely high processing speed and a saturation effect at high LNC levels. In terms of non-parametric regression approaches, we showed that the RF method comprised the best-performing algorithm (i.e., R2 = 0.79, RMSE = 0.33), also with a fast processing speed. The use of a physical retrieval method remains challenging for LNC estimations because of undeterminable input variables and low prediction accuracies.

Author Contributions

X.Y. and Y.Z. conceived and designed the experiments; W.L., J.J., Y.L. and Y.Z. performed the experiments; Y.L. analyzed the data; H.Z. and X.Y. wrote the paper. All authors contributed to the interpretation of results and editing of the manuscript.

Funding

This research was funded by the National Key Research and Development Program of China (2016YFD0300601), the National Natural Science Foundation of China (31671582), Jiangsu Qinglan Project, the 111 project (B16026), Jiangsu Collaborative Innovation Center for Modern Crop Production (JCICMCP), the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD), Qinghai Project of Transformation of Scientific and Technological Achievements (2018-NK-126), and Jiangsu Province Key Technologies R&D Program (BE2016375).

Acknowledgments

The authors would like to thank all reviewers and editors for their comments on this paper.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

UAVunmanned aerial vehicle
RSremote sensing
LNCleaf nitrogen content
LAIleaf area index
LCCleaf chlorophyll content
SPADsoil and plant analyzer development
RVIratio vegetation index
DVIdifference vegetation index
NDVInormalized difference vegetation index
RDVIrenormalized difference vegetation index
SAVIsoil adjusted vegetation index
OSAVIoptimized soil adjusted vegetation index
VIoptoptimized vegetation index
MSRmodified sample ratio
EVIenhanced vegetation index
MCARImodified chlorophyll absorption in reflectance index
TCARItransformed chlorophyll absorption in reflectance index
TBIthree-band index
VOGVogelmann index
MTCIMERIS terrestrial chlorophyll index
LSLRleast-squares linear
PCRprincipal component
PLSRpartial least-squares regression
ANNartificial neutral networks
DTdecision trees
RTregression trees
BaTbagging trees
BoTboosting trees
RFrandom forest
RVMrelevance vector machine
KRRkernel ridge
GPRGaussian processes regressions
VH-GPRvariational heteroscedastic GPR
ELMextreme learning machines
RTMradiative transfer model
LUTlook-up-table
R2determination coefficient
RMSEroot mean square error
RRMSErelative root mean square error
ILSincident light sensor
GCPground control point
ROIregion of interest

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Figure 1. The UAV equipped with multispectral camera used in this study.
Figure 1. The UAV equipped with multispectral camera used in this study.
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Figure 2. Comparison between measured and estimated LNC values with the best performing VI.
Figure 2. Comparison between measured and estimated LNC values with the best performing VI.
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Figure 3. Comparison of measured and estimated LNC values derived using the RF modeling algorithm (a) and MSE values for this model at different spectral bands (b).
Figure 3. Comparison of measured and estimated LNC values derived using the RF modeling algorithm (a) and MSE values for this model at different spectral bands (b).
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Figure 4. Empirical linear relationship between LCC and LNC values (a). Measured versus estimated LNC values derived from the most effective LUT-based inversion scheme (Table 8) (b).
Figure 4. Empirical linear relationship between LCC and LNC values (a). Measured versus estimated LNC values derived from the most effective LUT-based inversion scheme (Table 8) (b).
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Table 1. Details of the three field experiments.
Table 1. Details of the three field experiments.
ExperimentYearCultivarN Rate (kg/ha)Planting Density (plants/ha)Sampling DateGrowth StageN
Exp. 12013–2014Yangmai 18
Shengxuan 6
0, 100, 3001.5 × 106
3.0 × 106
14 March
9/15/23 April
6 May
Jointing, Booting, Heading, Anthesis, Filling159
Exp. 22013–2014Xumai 30
Ningmai 13
0, 75, 150, 225, 3002.4 × 10614 March
9/15/23 April
6 May
Jointing, Booting, Heading, Anthesis, Filling135
Exp. 32014–2015Yangmai 18
Shengxuan 6
0, 100, 3001.5 × 106
2.4 × 106
26 March
8/17/25 April
6 May
Jointing, Booting, Heading, Anthesis, Filling164
Table 2. Specifications of UAV and Mini-MCA multispectral camera.
Table 2. Specifications of UAV and Mini-MCA multispectral camera.
UAVCamera
Weight (g)2050Weight (g)700
Battery weight (g)520Geometric resolution (pixel)1280 × 1024
Maximum payload (g)2500Radiometric resolution (bit)10
Flight duration (min)8–41Speed (frame/s)1.3
Radius (m)1000Focal length (mm)9.6
Table 3. Commonly used vegetation indices.
Table 3. Commonly used vegetation indices.
IndexFormulaReference
Two-band
Ratio VI (RVI)Rλ1/Rλ2[31]
Difference VI (DVI)Rλ1 − Rλ2[31]
NDVI(Rλ1 − Rλ2)/(Rλ1 + Rλ2)[32]
Renormalized difference VI (RDVI)(Rλ1 − Rλ2)/(Rλ1 + Rλ2)0.5[33]
Soil adjusted VI (SAVI)1.5(Rλ1 − Rλ2)/(Rλ1 + Rλ2 + 0.5)[34]
Optimized soil adjusted VI (OSAVI)(1 + 0.16)(Rλ1 − Rλ2)/(Rλ1 + Rλ2 + 0.16)[35]
Optimized VI (VIopt)(1 + 0.45)(Rλ12 + 1)/(Rλ2 + 0.45)[36]
Modified sample ratio (MSR)((Rλ1/Rλ2) − 1)/(SQRT((Rλ1/Rλ2) + 1))[37]
Three-band
Enhanced VI (EVI)2.5(Rλ1 − Rλ2)/(Rλ1 + 6Rλ2 − 7.5Rλ3 + 1)[38]
Modified normalized difference (mND)(Rλ1 − Rλ2)/(Rλ1 + Rλ2 − 2Rλ3)[39]
Modified sample ratio (mSR)(Rλ1 − Rλ2)/(Rλ3 − Rλ2)[39]
Modified chlorophyll absorption in RI (MCARI)(Rλ1 − Rλ2 − 0.2(Rλ1 − Rλ3))(Rλ1/Rλ2)[40]
Transformed chlorophyll absorption in RI (TCARI)3((Rλ1 − Rλ2) − 0.2(Rλ1 − Rλ3)(Rλ1/Rλ2))[41]
Three-band index 1 (TBI1)(Rλ1 − Rλ2 − Rλ3)/(Rλ1 + Rλ2 + Rλ3)[42]
Three-band index 2 (TBI2)(Rλ1 − Rλ2 + 2Rλ3)/(Rλ1 + Rλ2 − 2Rλ3)[17]
Four-band
Vogelmann index (VOG)(Rλ1 − Rλ2)/(Rλ3 + Rλ4)[43]
MERIS terrestrial chlorophyll index (MTCI)(Rλ1 − Rλ2)/(Rλ3 − Rλ4)[44]
TCARI/OSAVITCARI/OSAVI[41]
MCARI/OSAVIMCARI/OSAVI[40]
Rλ1, Rλ2, Rλ3, and Rλ4 denote the reflectance of spectral bands randomly selected from 490 nm, 550 nm, 671 nm, 700 nm, and 800 nm.
Table 4. PROSAIL model input parameters.
Table 4. PROSAIL model input parameters.
ParametersUnitsRangeDistribution
Leaf: PROSPECT-5
Leaf structure index (N)Unitless1.2–1.8Gaussian
Leaf chlorophyll content (LCC)[μg/cm2]25–75Gaussian
Leaf dry matter content (Cm)[g/cm2]0.013
Leaf water content (Cw)[cm]0.018
Canopy: 4SAIL
Leaf area index (LAI)[m2/m2]0–7Gaussian
Soil scaling factor (αsoil)Unitless0.3
Average leaf angle (ALA)[°]60
Hotspot parameter (HotS)[m/m]0.2
Diffuse incoming solar radiation (skyl)[%]10
Sun zenith angle (θs)[°]25
View zenith angle (θv)[°]0
Sun-sensor azimuth angle (Φ)[°]0
Table 5. Calibration and validation of the models on different methods.
Table 5. Calibration and validation of the models on different methods.
MethodCalibrationValidation
Parametric10-fold cross validation, nine sub-datasets used for calibration (training), the rest for validation (test), repeated 10 times
Non-parametric
Physical-based modelLCC retrieved from PROSAIL, LNC obtained through the empirically linear model between LCC and LNC with measured dataAll retrieved LNC values compared with measured LNC values
Table 6. Cross-validation statistics and processing speed for the best-performing vegetation index (VI) under each formulation.
Table 6. Cross-validation statistics and processing speed for the best-performing vegetation index (VI) under each formulation.
VIOptimal BandsR2RMSE (%)Processing Speed (s)
Two-bandRVIλ1: 700; λ2: 8000.490.520.029
DVIλ1: 800; λ2: 7000.670.410.029
NDVIλ1: 800; λ2: 7000.490.520.046
RDVIλ1: 800; λ2: 7000.730.380.029
SAVIλ1: 800; λ2: 7000.730.380.030
OSAVIλ1: 800; λ2: 6710.700.400.029
VIoptλ1: 800; λ2: 6710.690.400.029
MSRλ1: 700; λ2: 8000.480.520.028
Three-bandEVIλ1: 800; λ2: 700; λ3: 4900.730.380.031
mNDλ1: 800; λ2: 700; λ3: 4900.690.400.029
mSRλ1: 700; λ2: 490; λ3: 8000.680.410.026
MCARIλ1: 550; λ2: 700; λ3: 8000.690.410.029
TCARIλ1: 550; λ2: 700; λ3: 8000.680.410.028
TBI1λ1: 671; λ2: 700; λ3: 5500.560.480.028
TBI2λ1: 800; λ2: 490; λ3: 6710.550.490.028
Four-bandVOGλ1: 490; λ2: 700; λ3: 800; λ4: 6710.700.400.027
MTCIλ1: 671; λ2: 800; λ3: 700; λ4: 4900.690.400.027
TCARI/OSAVIλ1: 550; λ2: 700; λ3: 800; λ4: 4900.660.420.028
MCARI/OSAVIλ1: 550; λ2: 700; λ3: 800; λ4: 4900.660.420.028
The row in bold type denotes the best-performing VI.
Table 7. Performance of different non-parametric modeling algorithms in LNC estimation ranked according to RMSE values.
Table 7. Performance of different non-parametric modeling algorithms in LNC estimation ranked according to RMSE values.
Non-Parametric AlgorithmR2RMSE (%)Processing Speed (s)
Random Forest (RF)0.790.332.284
Bagging Trees (BaT)0.780.342.700
Kernel Ridge Regression (KRR)0.780.351.934
Neural Network (NN)0.770.3510.406
VH Gaussian Process Regression (VH-GPR)0.770.3517.059
Gaussian Process Regression (GPR)0.770.354.265
Extreme Learning Machine (ELM)0.760.3620.068
Least-Squares Linear Regression (LSLR)0.750.360.007
Boosting Trees (BoT)0.750.372.301
Relevance Vector Machine (RVM)0.750.37268.473
Partial Least-Squares Regression (PLSR)0.740.370.016
Principal Component Regression (PCR)0.730.380.009
Regression Trees (RT)0.690.400.616
Table 8. Performance of different regularization strategies used in the PROSAIL model ranked according to RMSE values.
Table 8. Performance of different regularization strategies used in the PROSAIL model ranked according to RMSE values.
Cost FunctionNoise (%)Multiple Solutions (%)R2RMSE (μg/cm2)Processing Speed (s)
K(x) = log(x)22990.817.052.04
K(x) = x(log(x)) − x4141.50.758.241.85
Neyman chi-square3710.50.748.741.86
W Kagan3710.50.748.741.85
Kullback-Leibler4511.50.818.981.92
Jeffreys-Kullback-Leibler4519.50.809.171.76
Bhattacharyya divergence4519.50.819.262.03
Pearson chi-square50430.789.331.85
L-divergence Lin4720.50.819.352.16
Shannon (1948)4720.50.819.351.98
Shannon entropy5021.50.819.451.82
Harmonique toussaint50210.819.501.85
K-divergence Lin5030.50.809.541.96
Negative exponential disparity4820.50.799.651.92
Exponential50480.5911.841.98
Normal distribution-LSE50500.4713.101.74
Geman and McClure50500.4613.161.79
K(x) = −log(x) + x39500.7913.191.98
Least absolute error50500.3415.161.75
K(x) = log(x) + 1/x50500.0717.611.96
Table 9. Relative RMSE (RRMSE, %) values for different wheat LNC estimation methods under different conditions.
Table 9. Relative RMSE (RRMSE, %) values for different wheat LNC estimation methods under different conditions.
Sub-GroupTreatmentDifferent Modeling Algorithms
RDVIRFLUT
Growth stageJointing16.011.416.53
Booting8.88.812.60
Heading10.09.912.80
Anthesis11.711.714.03
Filling17.916.222.92
VarietyYangmai 1813.111.316.34
Shengxuan 614.012.016.43
Xumai 3013.411.916.51
Ningmai 1310.410.715.41
Plant density1.5 × 106 plants/ha12.112.113.41
2.4 × 106 plants/ha12.411.716.30
3 × 106 plants/ha14.411.116.34
Year201412.011.20.14
201514.612.20.18

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Zheng, H.; Li, W.; Jiang, J.; Liu, Y.; Cheng, T.; Tian, Y.; Zhu, Y.; Cao, W.; Zhang, Y.; Yao, X. A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle. Remote Sens. 2018, 10, 2026. https://doi.org/10.3390/rs10122026

AMA Style

Zheng H, Li W, Jiang J, Liu Y, Cheng T, Tian Y, Zhu Y, Cao W, Zhang Y, Yao X. A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle. Remote Sensing. 2018; 10(12):2026. https://doi.org/10.3390/rs10122026

Chicago/Turabian Style

Zheng, Hengbiao, Wei Li, Jiale Jiang, Yong Liu, Tao Cheng, Yongchao Tian, Yan Zhu, Weixing Cao, Yu Zhang, and Xia Yao. 2018. "A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle" Remote Sensing 10, no. 12: 2026. https://doi.org/10.3390/rs10122026

APA Style

Zheng, H., Li, W., Jiang, J., Liu, Y., Cheng, T., Tian, Y., Zhu, Y., Cao, W., Zhang, Y., & Yao, X. (2018). A Comparative Assessment of Different Modeling Algorithms for Estimating Leaf Nitrogen Content in Winter Wheat Using Multispectral Images from an Unmanned Aerial Vehicle. Remote Sensing, 10(12), 2026. https://doi.org/10.3390/rs10122026

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