Inversion of maize leaf nitrogen using UAV hyperspectral imagery in breeding fields

Qiwen Cheng, Bingsun Wu, Huichun Ye, Yongyi Liang, Yingpu Che, Anting Guo, Zixuan Wang, Zhiqiang Tao, Wenwei Li, Jingjing Wang

Abstract


Nitrogen (N) as a pivotal factor in influencing the growth, development, and yield of maize. Monitoring the N status of maize rapidly and non-destructive and real-time is meaningful in fertilization management of agriculture, based on unmanned aerial vehicle (UAV) remote sensing technology. In this study, the hyperspectral images were acquired by UAV and the leaf nitrogen content (LNC) and leaf nitrogen accumulation (LNA) were measured to estimate the N nutrition status of maize. 24 vegetation indices (VIs) were constructed using hyperspectral images, and four prediction models were used to estimate the LNC and LNA of maize. The models include a single linear regression model, multivariable linear regression (MLR) model, random forest regression (RFR) model, and support vector regression (SVR) model. Moreover, the model with the highest prediction accuracy was applied to invert the LNC and LNA of maize in breeding fields. The results of the single linear regression model with 24 VIs showed that normalized difference chlorophyll (NDchl) had the highest prediction accuracy for LNC (R2, RMSE, and RE were 0.72, 0.21, and 12.19%, respectively) and LNA (R2, RMSE, and RE were 0.77, 0.26, and 14.34%, respectively). And then, 24 VIs were divided into 13 important VIs and 11 unimportant VIs. Three prediction models for LNC and LNA were constructed using 13 important VIs, and the results showed that RFR and SVR models significantly enhanced the prediction accuracy of LNC and LNA compared to the multivariable linear regression model, in which RFR model had the highest prediction accuracy for the validation dataset of LNC (R2, RMSE, and RE were 0.78, 0.16, and 8.83%, respectively) and LNA (R2, RMSE, and RE were 0.85, 0.19, and 9.88%, respectively). This study provides a theoretical basis for N diagnosis and precise management of crop production based on hyperspectral remote sensing in precision agriculture.
Keywords: maize, nitrogen, hyperspectral imagery, vegetation index, UAV, random forest regression, support vector regression
DOI: 10.25165/j.ijabe.20241703.8663

Citation: Cheng Q W, Wu B S, Ye H C, Liang Y Y, Che Y P, Guo A T, et al. Inversion of maize leaf nitrogen using UAV hyperspectral imagery in breeding fields. Int J Agric & Biol Eng, 2024; 17(3): 144-155.

Keywords


maize, nitrogen, hyperspectral imagery, vegetation index, UAV, random forest regression, support vector regression

Full Text:

PDF

References


Saeed M S, Saeed A. Health benefits of maize crop - An overview. Current Research in Agriculture and Farming, 2020; 1(3): 5–8.

Lai Z L, Fan J L, Yang R, Xu X Y, Liu L J, Li S E, et al. Interactive effects of plant density and nitrogen rate on grain yield, economic benefit, water productivity and nitrogen use efficiency of drip-fertigated maize in northwest China. Agricultural Water Management, 2022; 263: 107453.

Anonymous. Statistical Bulletin on National Economic and Social Development of the People’s Republic of China in 2022. Available:http://www.stats.gov.cn/sj/zxfb/202302/t20230228_1919011.html. Accessed on [2023-02-28].

Gezahegn A M. Role of integrated nutrient management for sustainable maize production. International Journal of Agronomy, 2021; 2021: 9982884.

Rogers A R, Dunne J C, Romay C, Bohn M, Buckler E S, Ciampitti I A, et al. The importance of dominance and genotype-by-environment interactions on grain yield variation in a large-scale public cooperative maize experiment. G3, 2021; 11(2): jkaa050.

Xia Y H, Li J, Hao P H, Wang K, Lei B, Li H L, et al. Discovery of root-lesion nematode (Pratylenchus scribneri) on corn in Hainan province of China. Plant Disease, 2022; 106(7): 1999.

Han E Z, Huang Q Y. Global commodity markets, Chinese demand for maize, and deforestation in Northern Myanmar. Land, 2021; 10(11): 1232.

Miao X X, Miao Y, Liu Y, Tao S H, Zheng H B, Wang J M, et al. Measurement of nitrogen content in rice plant using near infrared spectroscopy combined with different PLS algorithms. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2023; 284: 121733.

Mekonnen H, Kibret M. The roles of plant growth promoting rhizobacteria in sustainable vegetable production in Ethiopia. Chemical and Biological Technologies in Agriculture, 2021; 8: 15.

Win K T, Oo A Z, Yokoyama T. Plant growth and yield response to salinity stress of rice grown under the application of different nitrogen levels and Bacillus pumilus Strain TUAT-1. Crops, 2022; 2(4): 435–444.

Nasar J, Khan W, Khan M Z, Gitari H I, Gbolayori J F, Moussa A A, et al. Photosynthetic activities and photosynthetic nitrogen use efficiency of maize crop under different planting patterns and nitrogen fertilization. Journal of Soil Science and Plant Nutrition, 2021; 21: 2274–2284.

Xu X G, Fan L L, Li Z H, Meng Y, Feng H K, Yang H, et al. Estimating leaf nitrogen content in corn based on information fusion of multiple-sensor imagery from UAV. Remote Sensing, 2021; 13(3): 340.

Yan S C, Wu Y, Fan J L, Zhang F C, Qiang S C, Zheng J, et al. Effects of water and fertilizer management on grain filling characteristics, grain weight and productivity of drip-fertigated winter wheat. Agricultural Water Management, 2019; 213: 983–995.

Zhang C, Rees R M, Ju X T. Cropping system design can improve nitrogen use efficiency in intensively managed agriculture. Environmental Pollution, 2021; 280: 116967.

Shi P H, Wang Y, Xu J M, Zhao Y L, Yang B L, Yuan Z Q, et al. Rice nitrogen nutrition estimation with RGB images and machine learning methods. Computers and Electronics in Agriculture, 2021; 180: 105860.

Sun H, Feng M C, Yang W D, Bi R T, Sun J J, Zhao C Q, et al. Monitoring leaf nitrogen accumulation with optimized spectral index in winter wheat under different irrigation regimes. Frontiers in Plant Science, 2022; 13: 913240.

Tan C W, Du Y, Zhou J, Wang D L, Luo M, Zhang Y J, et al. Analysis of different hyperspectral variables for diagnosing leaf nitrogen accumulation in wheat. Frontiers in Plant Science, 2018; 9: 674.

Chu X, Guo Y J, He J Y, Yao X, Zhu Y, Cao W X, et al. Comparison of different hyperspectral vegetation indices for estimating canopy leaf nitrogen accumulation in rice. Agronomy Journal, 2014; 106(5): 1911–1920.

Pan Y Y, Wu W X, Zhang J W, Zhao Y J, Zhang J Y, Gu Y Y, et al. Estimating leaf nitrogen and chlorophyll content in wheat by correcting canopy structure effect through multi-angular remote sensing. Computers and Electronics in Agriculture, 2023; 208: 107769.

Cao C L, Wang T L, Gao M F, Li Y, Li D D, Zhang H J. Hyperspectral inversion of nitrogen content in maize leaves based on different dimensionality reduction algorithms. Computers and Electronics in Agriculture, 2021; 190: 106461.

Duan D D, Zhao C J, Li Z H, Yang G J, Yang W D. Estimating total leaf nitrogen concentration in winter wheat by canopy hyperspectral data and nitrogen vertical distribution. Journal of Integrative Agriculture, 2019; 18(7): 1562–1570.

Berger K, Verrelst J, Féret J B, Wang Z, Wocher M, Strathmann M, et al. Crop nitrogen monitoring: Recent progress and principal developments in the context of imaging spectroscopy missions. Remote Sensing of Environment, 2020; 242: 111758.

Chapman H D, Pratt P F. Methods of analysis for soils, plants and waters. Soil Science, 1962; 93(1): 68.

Foomani K S, Abadi S A V, Kavoosi M, Zakerin H, Yazdani M. The effect of periodic irrigation and different amounts of nitrogen fertilizer on yield and yield components of rice. Communications in Soil Science and Plant Analysis, 2020; 52(1): 22–31.

Chlingaryan A, Sukkarieh S, Whelan B. Machine learning approaches for crop yield prediction and nitrogen status estimation in precision agriculture: A review. Computers and Electronics in Agriculture, 2018; 151: 61–69.

Li Z H, Li Z H, Fairbairn D, Li N, Xu B, Feng H K, et al. Multi-LUTs method for canopy nitrogen density estimation in winter wheat by field and UAV hyperspectral. Computers and Electronics in Agriculture, 2019; 162: 174–182.

Fu Y Y, Yang G J, Li Z H, Song X Y, Li Z H, Xu X G, et al. Winter wheat nitrogen status estimation using UAV-based RGB imagery and gaussian processes regression. Remote Sensing, 2020; 12(22): 3778.

Xu S Z, Xu X G, Blacker C, Gaulton R, Zhu Q Z, Yang M, et al. Estimation of leaf nitrogen content in rice using vegetation indices and feature variable optimization with information fusion of multiple-sensor images from UAV. Remote Sensing, 2023; 15(3): 854.

Kira O, Linker R, Gitelson A. Non-destructive estimation of foliar chlorophyll and carotenoid contents: Focus on informative spectral bands. International Journal of Applied Earth Observation and Geoinformation, 2015; 38: 251–260.

Hunt Jr E R, Doraiswamy P C, McMurtrey J E, Daughtry C S T, Perry E M, Akhmedov B. A visible band index for remote sensing leaf chlorophyll content at the canopy scale. International journal of applied earth observation and Geoinformation, 2013; 21: 103–112.

Abulaiti Y, Sawut M, Maimaitiaili B, Chunyue M. A possible fractional order derivative and optimized spectral indices for assessing total nitrogen content in cotton. Computers and Electronics in Agriculture, 2020; 171: 105275.

Tao H H, Feng H K, Xu L J, Miao M K, Long H L, Yue J B, et al. Estimation of crop growth parameters using UAV-based hyperspectral remote sensing data. Sensors, 2020; 20(5): 1296.

Monforte P, Ragusa M A. Temperature trend analysis and investigation on a case of variability climate. Mathematics, 2022; 10(13): 2202.

Jin X L, Zarco-Tejada P J, Schmidhalter U, Reynolds M P, Hawkesford M J, Varshney R K, et al. High-throughput estimation of crop traits: A review of ground and aerial phenotyping platforms. IEEE Geoscience and Remote Sensing Magazine, 2020; 9(1): 200–231.

Jung H J, Tajima R, Ye R L, Hashimoto N, Yang Y, Yamamoto S, et al. Utilization of UAV remote sensing in plant-based field experiments: A case study of the evaluation of LAI in a small-scale sweetcorn experiment. Agriculture, 2023; 13(3): 561.

Delavarpour N, Koparan C, Nowatzki J, Bajwa S, Sun X. A technical study on UAV characteristics for precision agriculture applications and associated practical challenges. Remote Sensing, 2021; 13(6): 1204.

Liu W, Zou S S, Xu X L, Gu Q Y, He W Z, Huang J, et al. Development of UAV-based shot seeding device for rice planting. Int J Agric & Biol Eng, 2022; 15(6): 1–7.

Bouguettaya A, Zarzour H, Kechida A, Taberkit A M. A survey on deep learning-based identification of plant and crop diseases from UAV-based aerial images. Cluster Computing, 2023; 26(2): 1297–1317.

Mothapo M C, Dube T, Abdel-Rahman E, Sibanda M. Progress in the use of geospatial and remote sensing technologies in the assessment and monitoring of tomato crop diseases. Geocarto International, 2022; 37(16): 4784–4804.

Lukas V, Huňady I, Kintl A, Mezera J, Hammerschmiedt T, Sobotková J, et al. Using UAV to identify the optimal vegetation index for yield prediction of oil seed rape (Brassica napus L.) at the flowering stage. Remote Sensing, 2022; 14(19): 4953.

Cheng E H, Zhang B, Peng D L, Zhong L H, Yu L, Liu Y, et al. Wheat yield estimation using remote sensing data based on machine learning approaches. Frontiers in Plant Science, 2022; 13: 1090970.

Gong Y, Yang K L, Lin Z H, Fang S H, Wu X T, Zhu R S, et al. Remote estimation of leaf area index (LAI) with unmanned aerial vehicle (UAV) imaging for different rice cultivars throughout the entire growing season. Plant Methods, 2021; 17(1): 88.

Yue J B, Feng H K, Li Z H, Zhou C Q, Xu K J. Mapping winter-wheat biomass and grain yield based on a crop model and UAV remote sensing. International Journal of Remote Sensing, 2021; 42(5): 1577–1601.

Wang Q, Che Y P, Shao K, Zhu J Y, Wang R L, Sui Y, et al. Estimation of sugar content in sugar beet root based on UAV multi-sensor data. Computers and Electronics in Agriculture, 2022; 203: 107433.

Zhou Y M, Jiang M J. Comparison of inversion method of maize leaf area index based on UAV hyperspectral remote sensing. Multimedia Tools and Applications, 2020; 79: 16385–16401.

Lu B, Dao P D, Liu J G, He Y H, Shang J L. Recent advances of hyperspectral imaging technology and applications in agriculture. Remote Sensing, 2020; 12(16): 2659.

Guo A T, Ye H C, Huang W J, Qian B X, Wang J J, Lan Y B, et al. Inversion of maize leaf area index from UAV hyperspectral and multispectral imagery. Computers and Electronics in Agriculture, 2023; 212: 108020.

Lu J S, Yang T C, Su X, Qi H, Yao X, Cheng T, et al. Monitoring leaf potassium content using hyperspectral vegetation indices in rice leaves. Precision Agriculture, 2020; 21: 324–348.

Wen P F, Shi Z J, Li A, Ning F, Zhang Y H, Wang R, et al. Estimation of the vertically integrated leaf nitrogen content in maize using canopy hyperspectral red edge parameters. Precision Agriculture, 2021; 22: 984–1005.

Guo J B, Zhang J J, Xiong S P, Zhang Z Y, Wei Q Q, Zhang W, et al. Hyperspectral assessment of leaf nitrogen accumulation for winter wheat using different regression modeling. Precision Agriculture, 2021; 22: 1634–1658.

Patel M K, Ryu D, Western A W, Suter H, Young I M. Which multispectral indices robustly measure canopy nitrogen across seasons: Lessons from an irrigated pasture crop. Computers and Electronics in Agriculture, 2021; 182: 106000.

Chen X K, Li F L, Shi B T, Chang Q R. Estimation of winter wheat plant nitrogen concentration from UAV hyperspectral remote sensing combined with machine learning methods. Remote Sensing, 2023; 15(11): 2831.

Ta N, Chang Q R, Zhang Y M. Estimation of apple tree leaf chlorophyll content based on machine learning methods. Remote Sensing, 2021; 13(19): 3902.

Fu Y Y, Yang G J, Li Z H, Li H L, Li Z H, Xu X G, et al. Progress of hyperspectral data processing and modelling for cereal crop nitrogen monitoring. Computers and Electronics in Agriculture, 2020; 172: 105321.

Gahrouei O R, McNairn H, Hosseini M, Homayouni S. Estimation of crop biomass and leaf area index from multitemporal and multispectral imagery using machine learning approaches. Canadian Journal of Remote Sensing, 2020; 46(1): 84–99.

Peng J X, Manevski K, Kørup K, Larsen R, Andersen M N. Random forest regression results in accurate assessment of potato nitrogen status based on multispectral data from different platforms and the critical concentration approach. Field Crops Research, 2021; 268: 108158.

Zhang Y, Xia C Z, Zhang X Y, Cheng X H, Feng G Z, Wang Y, et al. Estimating the maize biomass by crop height and narrowband vegetation indices derived from UAV-based hyperspectral images. Ecological Indicators, 2021; 129: 107985.

Ma L L, Chen X Y, Zhang Q, Lin J, Yin C X, Ma Y R, et al. Estimation of nitrogen content based on the hyperspectral vegetation indexes of interannual and multi-temporal in cotton. Agronomy, 2022; 12(6): 1319.

Yang H B, Yin H, Li F, Hu Y C, Yu K. Machine learning models fed with optimized spectral indices to advance crop nitrogen monitoring. Field Crops Research, 2023; 293: 108844.

Gao J, Shahid R, Ji X, Li S J. Climate change resilience and sustainable tropical agriculture: Farmers’ perceptions, reactive adaptations and determinants of reactive adaptations in Hainan, China. Atmosphere, 2022; 13(6): 955.

Hu N, Hu J C, Jiang X D, Xiao W, Yao K M, Li L, et al. Application of the maximum threshold distances to reduce gene flow frequency in the coexistence between genetically modified (GM) and non‐GM maize. Evolutionary Applications, 2022; 15(3): 471–483.

Xue L H, Cao W X, Luo W H, Dai T B, Zhu Y. Monitoring leaf nitrogen status in rice with canopy spectral reflectance. Agronomy Journal, 2004; 96(1): 135–142.

Zarco-Tejada P J, Miller J R, Noland T L, Mohammed G H, Sampson P H. Scaling-up and model inversion methods with narrowband optical indices for chlorophyll content estimation in closed forest canopies with hyperspectral data. IEEE Transactions on Geoscience and Remote Sensing, 2001; 39(7): 1491–1507.

Rouse J W. Monitoring the vernal advancement of retrogradation of natural vegetation. NASA/GSFC, TypeIII, Final report, Greenbelt, MD, 1974; pp.1–371.

Jordan C F. Derivation of leaf area index from light quality of the forest floor. Ecology, 1969; 50(4): 663–666.

Blackburn G A. Quantifying chlorophylls and caroteniods at leaf and canopy scales: An evaluation of some hyperspectral approaches. Remote Sensing of Environment, 1998; 66(3): 273–285.

Gitelson A, Merzlyak M N. Quantitative estimation of chlorophyll-a using reflectance spectra: Experiments with autumn chestnut and maple leaves. Journal of Photochemistry and Photobiology B: Biology, 1994; 22(3): 247–252.

Fitzgerald G J, Rodriguez D, Christensen L K, Belford R, Sadras V O, Clarke T R. Spectral and thermal sensing for nitrogen and water status in rainfed and irrigated wheat environments. Precision Agriculture, 2006; 7(4): 233–248.

Jiang Z Y, Huete A R, Didan K, Miura T. Development of a two-band enhanced vegetation index without a blue band. Remote Sensing of Environment, 2008; 112(10): 3833–3845.

Gitelson A A, Keydan G P, Merzlyak M N. Three-band model for noninvasive estimation of chlorophyll, carotenoids, and anthocyanin contents in higher plant leaves. Geophysical Research Letters, 2006; 33(11): 2006GL026457.

Dash J, Curran P J. Evaluation of the MERIS terrestrial chlorophyll index (MTCI). Advances in Space Research, 2007; 39(1): 100–104.

Castro K L, Sanchez-Azofeifa G A. Changes in spectral properties, chlorophyll content and internal mesophyll structure of senescing Populus balsamifera and Populus tremuloides leaves. Sensors, 2008; 8(1): 51–69.

Rondeaux G, Steven M, Baret F. Optimization of soil-adjusted vegetation indices. Remote Sensing of Environment, 1996; 55(2): 95–107.

Daughtry C S, Walthall C L, Kim M S, De Colstoun E B, McMurtrey Iii J E. Estimating corn leaf chlorophyll concentration from leaf and canopy reflectance. Remote Sensing of Environment, 2000; 74(2): 229–239.

Gitelson A A, Kaufman Y J, Merzlyak M N. Use of a green channel in remote sensing of global vegetation from EOS-MODIS. Remote Sensing of Environment, 1996; 58(3): 289–298.

Chen J M. Evaluation of vegetation indices and a modified simple ratio for boreal applications. Canadian Journal of Remote Sensing, 1996; 22(3): 229–242.

Qi J, Chehbouni A, Huete A R, Kerr Y H, Sorooshian S. A modified soil adjusted vegetation index. Remote Sensing of Environment, 1994; 48(2): 119–126.

Huete A R. A soil-adjusted vegetation index (SAVI). Remote Sensing of Environment, 1988; 25(3): 295–309.

Lemaire G, Jeuffroy M H, Gastal F. Diagnosis tool for plant and crop N status in vegetative stage: Theory and practices for crop N management. European Journal of Agronomy, 2008; 28(4): 614–624.

Li F, Mistele B, Hu Y C, Chen X P, Schmidhalter U. Comparing hyperspectral index optimization algorithms to estimate aerial N uptake using multi-temporal winter wheat datasets from contrasting climatic and geographic zones in China and Germany. Agricultural and Forest Meteorology, 2013; 180: 44–57.

Feng W, Guo B B, Zhang H Y, He L, Zhang Y S, Wang Y H, et al. Remote estimation of above ground nitrogen uptake during vegetative growth in winter wheat using hyperspectral red-edge ratio data. Field Crops Research, 2015; 180: 197–206.

Guyot G, Baret F, Major D. High spectral resolution: Determination of spectral shifts between the red and the near infrared. International Archives of Photogrammetry and Remote Sensing, 1988; 11: 750–760.

Jin J, Pratama B A, Wang Q. Tracing leaf photosynthetic parameters using hyperspectral indices in an alpine deciduous forest. Remote Sensing, 2020; 12(7): 1124.

Chen X Y, Lyu X, Ma L L, Chen A Q, Zhang Q, Zhang Z. Optimization and validation of hyperspectral estimation capability of cotton leaf nitrogen based on SPA and RF. Remote Sensing, 2022; 14(20): 5201.

Song X, Xu D Y, Huang C C, Zhang K K, Huang S M, Guo D D, et al. Monitoring of nitrogen accumulation in wheat plants based on hyperspectral data. Remote Sensing Applications: Society and Environment, 2021; 23: 100598.

Dong T F, Meng J H, Shang J L, Liu J G, Wu B F. Evaluation of chlorophyll-related vegetation indices using simulated Sentinel-2 data for estimation of crop fraction of absorbed photosynthetically active radiation. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2015; 8(8): 4049–4059.

Nguy-Robertson A L, Gitelson A A. Algorithms for estimating green leaf area index in C3 and C4 crops for MODIS, Landsat TM/ETM+, MERIS, Sentinel MSI/OLCI, and Venµs sensors. Remote Sensing Letters, 2015; 6(5): 360–369.

Li W, Li D, Liu S Y, Baret F, Ma Z Y, He C, et al. RSARE: A physically-based vegetation index for estimating wheat green LAI to mitigate the impact of leaf chlorophyll content and residue-soil background. ISPRS Journal of Photogrammetry and Remote Sensing, 2023; 200: 138–152.

Ramos-García C A, Martínez-Martínez L J, Bernal-Riobo J H. Estimating chlorophyll and nitrogen contents in maize leaves (Zea mays L.) with spectroscopic analysis. Revista Colombiana de Ciencias Hortícolas, 2022; 16(1): 13398.

Prey L, Von Bloh M, Schmidhalter U. Evaluating RGB imaging and multispectral active and hyperspectral passive sensing for assessing early plant vigor in winter wheat. Sensors, 2018; 18(9): 2931.

Geipel J, Link J, Wirwahn J A, Claupein W. A programmable aerial multispectral camera system for in-season crop biomass and nitrogen content estimation. Agriculture, 2016; 6(1): 4.

Verma B, Prasad R, Srivastava P K, Singh P. Retrieval of leaf area index using inversion algorithm. In: 2022 12th Workshop on Hyperspectral Imaging and Signal Processing: Evolution in Remote Sensing (WHISPERS), Rome: IEEE, 2022; pp.1–4.

Fan X L, Lyu X, Gao P, Zhang L F, Zhang Z, Zhang Q, et al. Establishment of a monitoring model for the cotton leaf area index based on the canopy reflectance spectrum. Land, 2023; 12(1): 78.

Tang Z J, Guo J J, Xiang Y Z, Lu X H, Wang Q, Wang H D, et al. Estimation of leaf area index and above-ground biomass of winter wheat based on optimal spectral index. Agronomy, 2022; 12(7): 1729.

Liu S S, Bai X H, Zhu G G, Zhang Y, Li L T, Ren T, et al. Remote estimation of leaf nitrogen concentration in winter oilseed rape across growth stages and seasons by correcting for the canopy structural effect. Remote Sensing of Environment, 2023; 284: 113348.

Liu J, Pattey E, Jégo G. Assessment of vegetation indices for regional crop green LAI estimation from Landsat images over multiple growing seasons. Remote Sensing of Environment, 2012; 123: 347–358.

Guo F X, Feng Q, Yang S, Yang W X. Estimation of potato canopy nitrogen content based on hyperspectral index optimization. Agronomy, 2023; 13(7): 1693.

Zhu Y, Li Y X, Feng W, Tian Y C, Yao X, Cao W X. Monitoring leaf nitrogen in wheat using canopy reflectance spectra. Canadian Journal of Plant Science, 2006; 86(4): 1037–1046.

He L, Zhang H Y, Zhang Y S, Song X, Feng W, Kang G Z, et al. Estimating canopy leaf nitrogen concentration in winter wheat based on multi-angular hyperspectral remote sensing. European Journal of Agronomy, 2016; 73: 170–185.

Inoue Y, Sakaiya E, Zhu Y, Takahashi W. Diagnostic mapping of canopy nitrogen content in rice based on hyperspectral measurements. Remote Sensing of Environment, 2012; 126: 210–221.

Miphokasap P, Honda K, Vaiphasa C, Souris M, Nagai M. Estimating canopy nitrogen concentration in sugarcane using field imaging spectroscopy. Remote Sensing, 2012; 4(6): 1651–1670.

Fu Y Y, Yang G J, Pu R L, Li Z H, Li H L, Xu X G, et al. An overview of crop nitrogen status assessment using hyperspectral remote sensing: Current status and perspectives. European Journal of Agronomy, 2021; 124: 126241.

Cabrera-Bosquet L, Molero G, Stellacci A, Bort J, Nogués S, Araus J. NDVI as a potential tool for predicting biomass, plant nitrogen content and growth in wheat genotypes subjected to different water and nitrogen conditions. Cereal Research Communications, 2011; 39(1): 147–159.

Yao X, Zhu Y, Tian Y C, Feng W, Cao W X. Exploring hyperspectral bands and estimation indices for leaf nitrogen accumulation in wheat. International Journal of Applied Earth Observation and Geoinformation, 2010; 12(2): 89–100.

Song X, Xu D Y, He L, Feng W, Wang Y H, Wang Z J, et al. Using multi-angle hyperspectral data to monitor canopy leaf nitrogen content of wheat. Precision Agriculture, 2016; 17: 721–736.

Alkhaled A, Townsend P A, Wang Y. Remote sensing for monitoring potato nitrogen status. American Journal of Potato Research, 2023; 100(1): 1–14.

Ye H C, Huang W J, Huang S Y, Wu B, Dong Y Y, Cui B. Remote estimation of nitrogen vertical distribution by consideration of maize geometry characteristics. Remote Sensing, 2018; 10(12): 1995.

Mallick J, AlMesfer M K, Singh V P, Falqi I I, Singh C K, Alsubih M, et al. Evaluating the NDVI-rainfall relationship in Bisha watershed, Saudi Arabia using non-stationary modeling technique. Atmosphere, 2021; 12(5): 593.

Sims D A, Gamon J A. Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages. Remote Sensing of Environment, 2002; 81(2-3): 337–354.

Li F L, Wang L, Liu J, Wang Y N, Chang Q R. Evaluation of leaf N concentration in winter wheat based on discrete wavelet transform analysis. Remote Sensing, 2019; 11(11): 1331.

Wang X X, Cai G S, Lu X P, Yang Z N, Zhang X J, Zhang Q G. Inversion of wheat leaf area index by multivariate red-edge spectral vegetation index. Sustainability, 2022; 14(23): 15875.

Yang H B, Li F, Hu Y C, Yu K. Hyperspectral indices optimization algorithms for estimating canopy nitrogen concentration in potato (Solanum tuberosum L.). International Journal of Applied Earth Observation and Geoinformation, 2021; 102: 102416.

Guo B B, Zhu Y J, Feng W, He L, Wu Y P, Zhou Y, et al. Remotely estimating aerial N uptake in winter wheat using red-edge area index from multi-angular hyperspectral data. Frontiers in Plant Science, 2018; 9: 675–688.

Fan K, Li F L, Chen X K, Li Z F, Mulla D J. Nitrogen balance index prediction of winter wheat by canopy hyperspectral transformation and machine learning. Remote Sensing, 2022; 14(14): 3504.

Homolová L, Malenovský Z, Clevers J G, García-Santos G, Schaepman M E. Review of optical-based remote sensing for plant trait mapping. Ecological Complexity, 2013; 15: 1–16.

Baret F, Houlès V, Guerif M. Quantification of plant stress using remote sensing observations and crop models: the case of nitrogen management. Journal of experimental botany, 2007; 58(4): 869–880.

Cartelat A, Cerovic Z G, Goulas Y, Meyer S, Lelarge C, Prioul J L, et al. Optically assessed contents of leaf polyphenolics and chlorophyll as indicators of nitrogen deficiency in wheat (Triticum aestivum L.). Field crops research, 2005; 91(1): 35–49.

Osco L P, Ramos A P M, Pereira D R, Moriya R A S, José Eduardo Creste. Predicting canopy nitrogen content in citrus-trees using random forest algorithm associated to spectral vegetation indices from UAV-imagery. Remote Sensing, 2019; 11(24): 2925.

Osco L P, Junior J M, Ramos A P M, Furuya D E G, Santana D C, Teodoro L P R, et al. Leaf nitrogen concentration and plant height prediction for maize using UAV-based multispectral imagery and machine learning techniques. Remote Sensing, 2020; 12(19): 3237.

Marang I J, Filipp.P, Weaver T B, Evans B J, Whelan B M, Bishop T F, et al. Machine learning optimised hyperspectral remote sensing retrieves cotton nitrogen status. Remote Sensing, 2021; 13(8): 1428.

Zha H N, Miao Y X, Wang T T, Li Y, Zhang J, Sun W C, et al. Improving unmanned aerial vehicle remote sensing-based rice nitrogen nutrition index prediction with machine learning. Remote Sensing, 2020; 12(2): 215.

Liu S Y, Zhang B, Yang W G, Chen T, Zhang H, Lin Y D, et al. Quantification of physiological parameters of rice varieties based on multi-spectral remote sensing and machine learning models. Remote Sensing, 2023; 15(2): 453.

Johansen K, Morton M J L, Malbeteau Y, Aragon B, Al-Mashharawi S, Ziliani M G, et al. Predicting biomass and yield in a tomato phenotyping experiment using UAV imagery and random forest. Frontiers in Artificial Intelligence, 2020; 3: 28.

Zhou K, Cheng T, Zhu Y, Cao W X, Ustin S L, Zheng H, et al. Assessing the impact of spatial resolution on the estimation of leaf nitrogen concentration over the full season of paddy rice using near-surface imaging spectroscopy data. Frontiers in Plant Science, 2018; 9: 964.

Inoue Y, Darvishzadeh R, Skidmore A. Hyperspectral assessment of ecophysiological functioning for diagnostics of crops and vegetation. In: Thenkabail P S, Lyon J G, Huete A (Ed. ), editors. Biophysical and biochemical characterization and plant species studies. CRC Press. 2018. pp.25–71.

Wang L, Chang Q R, Li F L, Yan L, Huang Y, Wang Q, et al. Effects of growth stage development on paddy rice leaf area index prediction models. Remote Sensing, 2019; 11(3): 361.

Chen X K, Li F L, Wang Y N, Shi B T, Hou Y H, Chang Q R. Estimation of winter wheat leaf area index based on UAV hyperspectral remote sensing. Transactions of the CSAE, 2020; 36(22): 40–49. (in Chinese)

Breiman L. Random Forests. Machine Learning, 2001; 45: 5–32.

Jiang J, Johansen K, Stanschewski C S, Wellman G, Mousa M A, Fiene G M, et al. Phenotyping a diversity panel of quinoa using UAV-retrieved leaf area index, SPAD-based chlorophyll and a random forest approach. Precision Agriculture, 2022; 23(3): 961–983.

Han L, Yang G J, Dai H Y, Xu B, Yang H, Feng H K, et al. Modeling maize above-ground biomass based on machine learning approaches using UAV remote-sensing data. Plant Methods, 2019; 15(1): 10.

Maxwell A E, Warner T A, Fang F. Implementation of machine-learning classification in remote sensing: An applied review. International Journal of Remote Sensing, 2018; 39(9): 2784–2817.

Polikar R. Ensemble based systems in decision making. IEEE Circuits and Systems Magazine, 2006; 6(3): 21–45.

Wang J J, Chen Y Y, Chen F F, Shi T Z, Wu G F. Wavelet-based coupling of leaf and canopy reflectance spectra to improve the estimation accuracy of foliar nitrogen concentration. Agricultural and Forest Meteorology, 2018; 248: 306–315.

Shah S H, Angel Y, Houborg R, Ali S, McCabe M F. A random forest machine learning approach for the retrieval of leaf chlorophyll content in wheat. Remote Sensing, 2019; 11(8): 920.

Qiu Z C, Ma F, Li Z W, Xu X B, Ge H X, Du C W. Estimation of nitrogen nutrition index in rice from UAV RGB images coupled with machine learning algorithms. Computers and Electronics in Agriculture, 2021; 189: 106421.

Sun Q, Jiao Q, Qian X, Liu L, Liu X, Dai H. Improving the retrieval of crop canopy chlorophyll content using vegetation index combinations. Remote Sensing, 2021; 13(3): 470.

Liang L, Di L P, Huang T, Wang J H, Lin L, Wang L J, et al. Estimation of leaf nitrogen content in wheat using new hyperspectral indices and a random forest regression algorithm. Remote Sensing, 2018; 10(12): 1940.

Singh H, Roy A, Setia R K, Pateriya B. Estimation of nitrogen content in wheat from proximal hyperspectral data using machine learning and explainable artificial intelligence (XAI) approach. Modeling Earth Systems and Environment, 2022; 8: 2505–2511.

Nigon T J, Yang C, Dias Paiao G, Mulla D J, Knight J F, Fernández F G. Prediction of early season nitrogen uptake in maize using high-resolution aerial hyperspectral imagery. Remote Sensing, 2020; 12(8): 1234.

Guo B B, Qi S L, Heng Y R, Duan J Z, Zhang H Y, Wu Y P, et al. Remotely assessing leaf N uptake in winter wheat based on canopy hyperspectral red-edge absorption. European Journal of Agronomy, 2017; 82: 113–124.

Li L T, Lu J W, Wang S Q, Ma Y, Wei Q Q, Li X K, et al. Methods for estimating leaf nitrogen concentration of winter oilseed rape (Brassica napus L.) using in situ leaf spectroscopy. Industrial Crops and Products, 2016; 91: 194–204.

Ryu C, Suguri M, Iida M, Umeda M, Lee C. Integrating remote sensing and GIS for prediction of rice protein contents. Precision Agriculture, 2011; 12: 378–394.

Wen P F, He J, Ning F, Wang R, Zhang Y H, Li J. Estimating leaf nitrogen concentration considering unsynchronized maize growth stages with canopy hyperspectral technique. Ecological Indicators, 2019; 107: 105590.

Wang L, Chen S S, Li D, Wang C Y, Jiang H, Zheng Q, et al. Estimation of paddy rice nitrogen content and accumulation both at leaf and plant levels from UAV hyperspectral imagery. Remote Sensing, 2021; 13(15): 2956.

Chen Q W, Mu X H, Chen F J, Yuan L X, Mi G H. Dynamic change of mineral nutrient content in different plant organs during the grain filling stage in maize grown under contrasting nitrogen supply. European Journal of Agronomy, 2016; 80: 137–153.

Mu X, Chen Q, Chen F, Yuan L, Mi G. Dynamic remobilization of leaf nitrogen components in relation to photosynthetic rate during grain filling in maize. Plant Physiology and biochemistry, 2018; 129: 27–34.

Lu J S, Cheng D L, Geng C M, Zhang Z T, Xiang Y Z, Hu T T. Combining plant height, canopy coverage and vegetation index from UAV-based RGB images to estimate leaf nitrogen concentration of summer maize. Biosystems Engineering, 2021; 202: 42–54.

Du B M, Ji H W, Peng C, Liu X J, Liu C J. Altitudinal patterns of leaf stoichiometry and nutrient resorption in Quercus variabilis in the Baotianman Mountains, China. Plant and Soil, 2017; 413: 193–202.

Huang Y T, Lu Y L, Ding Y, Yu Z B, Cheng H. Comparison of soil nutrient status in four types of forests in Bawangling of Hainan island. Journal of West China Forestry Science, 2013; 42(1): 64–69.

Lin Y Q, Wang A W, Su P, Fu H S. Distribution characteristics of soil nutrients in the western region of Hainan - Taking Baisha Li Autonomous County as an Example. China Tropical Agriculture, 2017; 14(1): 32–35.

Cambouris A N, Ziadi N, Perron I, Alotaibi K D, St. Luce M, Tremblay N. Corn yield components response to nitrogen fertilizer as a function of soil texture. Canadian Journal of Soil Science, 2016; 96(4): 386–399.

Zhao C X, Jia L H, Wang Y F, Wang M L, McGiffen Jr M E. Effects of different soil texture on peanut growth and development. Communications in Soil Science and Plant Analysis, 2015; 46(18): 2249–2257.

Jalota S K, Singh S, Chahal G B S, Ray S S, Panigraghy S, Singh K B. Soil texture, climate and management effects on plant growth, grain yield and water use by rainfed maize - wheat cropping system: Field and simulation study. Agricultural Water Management, 2010; 97(1): 83–90.

Li R F, Liu P, Dong S T, Zhang J W, Zhao B. Increased maize plant population induced leaf senescence, suppressed root growth, nitrogen uptake, and grain yield. Agronomy Journal, 2019; 111(4): 1581–1591.

Testa G, Reyneri A, Blandino M. Maize grain yield enhancement through high plant density cultivation with different inter-row and intra-row spacings. European Journal of Agronomy, 2016; 72: 28–37.




Copyright (c) 2024 International Journal of Agricultural and Biological Engineering

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.

2023-2026 Copyright IJABE Editing and Publishing Office