Towards an Improved High-Throughput Phenotyping Approach: Utilizing MLRA and Dimensionality Reduction Techniques for Transferring Hyperspectral Proximal-Based Model to Airborne Images

At present, it is critical to accurately monitor wheat crops to help decision-making processes in precision agriculture. This research aims to retrieve various wheat crop traits from hyperspectral data using machine learning regression algorithms (MLRAs) and dimensionality reduction (DR) techniques. This experiment was conducted in an agricultural field in Arborea, Oristano-Sardinia, Italy, with different factors such as cultivars, N-treatments, and soil ploughing conditions. Hyperspectral data were acquired on the ground using a full-range Spectral Evolution spectrometer (350–2500 nm). Four DR techniques, including (i) variable influence on projection (VIP), (ii) principal component analysis (PCA), (iii) vegetation indices (VIs), and (iv) spectroscopic feature (SF) calculation, were undertaken to reduce the dimension of the hyperspectral data while maintaining the information content. We used five MLRA models, including (i) partial least squares regression (PLSR), (ii) random forest (RF), (iii) support vector regression (SVR), (iv) Gaussian process regression (GPR), and (v) neural network (NN), to retrieve wheat traits at either leaf and canopy levels. The studied traits were leaf area index (LAI), leaf and canopy water content (LWC and CWC), leaf and canopy chlorophyll content (LCC and CCC), and leaf and canopy nitrogen content (LNC and CNC). MLRA models were able to accurately retrieve wheat traits at the canopy level with PLSR and NN indicating the highest modelling performance. On the contrary, MLRA models indicated less accurate retrievals of the leaf-level traits. DR techniques were found to notably improve the retrieval accuracy of crop traits. Furthermore, the generated models were re-calibrated using soil spectra and then transferred to an airborne dataset collected using a CASI-SASI hyperspectral sensor, allowing the estimation of wheat traits across the entire field. The predicted crop trait maps illustrated consistent patterns while also preserving the real-field characteristics well. Lastly, a statistical paired t-test was undertaken to conduct a proof of concept of wheat phenotyping analysis considering the different agricultural variables across the study site. N-treatment caused significant differences in wheat crop traits in many instances, whereas the observed differences were less pronounced between the cultivars. No particular impact of soil ploughing conditions on wheat crop characteristics was found. Using such combinations of MLRA and DR techniques based on hyperspectral data can help to effectively monitor crop traits throughout the cropping seasons and can also be readily applied to other agricultural settings to help both precision farming applications and the implementation of high-throughput phenotyping solutions.

[1]  M. Boschetti,et al.  Assessment of maize nitrogen uptake from PRISMA hyperspectral data through hybrid modelling , 2022, European journal of remote sensing.

[2]  Ana Belen Pascual Venteo,et al.  Prototyping Crop Traits Retrieval Models for CHIME: Dimensionality Reduction Strategies Applied to PRISMA Data , 2022, Remote. Sens..

[3]  B. Brinne,et al.  Data management for production quality deep learning models: Challenges and solutions , 2022, J. Syst. Softw..

[4]  M. Rossini,et al.  Hybrid retrieval of crop traits from multi-temporal PRISMA hyperspectral imagery. , 2022, ISPRS journal of photogrammetry and remote sensing : official publication of the International Society for Photogrammetry and Remote Sensing.

[5]  M. Boschetti,et al.  Evaluation of Hybrid Models to Estimate Chlorophyll and Nitrogen Content of Maize Crops in the Framework of the Future CHIME Mission , 2022, Remote. Sens..

[6]  H. Pelgrum,et al.  High spatio-temporal monitoring of century-old biochar effects on evapotranspiration through the ETLook model: a case study with UAV and satellite image fusion based on additive wavelet transform (AWT) , 2021, GIScience & Remote Sensing.

[7]  Philip A. Townsend,et al.  Airborne hyperspectral imaging of nitrogen deficiency on crop traits and yield of maize by machine learning and radiative transfer modeling , 2021, Int. J. Appl. Earth Obs. Geoinformation.

[8]  Thomas P. F. Dowling,et al.  The PRISMA imaging spectroscopy mission: overview and first performance analysis , 2021 .

[9]  Hongyan Yang,et al.  Classification of desert steppe species based on unmanned aerial vehicle hyperspectral remote sensing and continuum removal vegetation indices , 2021 .

[10]  C. Panigada,et al.  Mapping landscape canopy nitrogen content from space using PRISMA data , 2021, ISPRS journal of photogrammetry and remote sensing : official publication of the International Society for Photogrammetry and Remote Sensing.

[11]  Eduardo Francisco Caicedo Bravo,et al.  Dimensionality reduction of hyperspectral images of vegetation and crops based on self-organized maps , 2021, Information Processing in Agriculture.

[12]  Katja Berger,et al.  Remote and Proximal Assessment of Plant Traits , 2021, Remote. Sens..

[13]  I. Yule,et al.  Field spectroscopy of canopy nitrogen concentration in temperate grasslands using a convolutional neural network , 2021 .

[14]  Moussa El Jarroudi,et al.  Monitoring Wheat Leaf Rust and Stripe Rust in Winter Wheat Using High-Resolution UAV-Based Red-Green-Blue Imagery , 2020, Remote. Sens..

[15]  Jinfei Wang,et al.  Using Linear Regression, Random Forests, and Support Vector Machine with Unmanned Aerial Vehicle Multispectral Images to Predict Canopy Nitrogen Weight in Corn , 2020, Remote. Sens..

[16]  Jin Wu,et al.  High-throughput field phenotyping using hyperspectral reflectance and partial least squares regression (PLSR) reveals genetic modifications to photosynthetic capacity , 2019, Remote Sensing of Environment.

[17]  Arko Lucieer,et al.  Poppy crop capsule volume estimation using UAS remote sensing and random forest regression , 2018, Int. J. Appl. Earth Obs. Geoinformation.

[18]  Gustau Camps-Valls,et al.  Quantifying Vegetation Biophysical Variables from Imaging Spectroscopy Data: A Review on Retrieval Methods , 2018, Surveys in Geophysics.

[19]  Brenner Silva,et al.  Hyperspectral Data Analysis in R: The hsdar Package , 2018, Journal of Statistical Software.

[20]  David P. Roy,et al.  Adjustment of Sentinel-2 Multi-Spectral Instrument (MSI) Red-Edge Band Reflectance to Nadir BRDF Adjusted Reflectance (NBAR) and Quantification of Red-Edge Band BRDF Effects , 2017, Remote. Sens..

[21]  Jorge Cadima,et al.  Principal component analysis: a review and recent developments , 2016, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[22]  Tae Kyun Kim,et al.  T test as a parametric statistic , 2015, Korean journal of anesthesiology.

[23]  Zhihao Qin,et al.  Estimation of Crop LAI using hyperspectral vegetation indices and a hybrid inversion method , 2015 .

[24]  Kidakan Saithanu,et al.  CUTOFF THRESHOLD OF VARIABLE IMPORTANCE IN PROJECTION FOR VARIABLE SELECTION , 2014 .

[25]  Jürgen Schmidhuber,et al.  Deep learning in neural networks: An overview , 2014, Neural Networks.

[26]  Craig S. T. Daughtry,et al.  A visible band index for remote sensing leaf chlorophyll content at the canopy scale , 2013, Int. J. Appl. Earth Obs. Geoinformation.

[27]  X. Yao,et al.  Assessing newly developed and published vegetation indices for estimating rice leaf nitrogen concentration with ground- and space-based hyperspectral reflectance , 2011 .

[28]  A. McBratney,et al.  Critical review of chemometric indicators commonly used for assessing the quality of the prediction of soil attributes by NIR spectroscopy , 2010 .

[29]  Yafit Cohen,et al.  SWIR-based spectral indices for assessing nitrogen content in potato fields , 2010 .

[30]  Chaoyang Wu,et al.  Estimating chlorophyll content from hyperspectral vegetation indices : Modeling and validation , 2008 .

[31]  M. Schaepman,et al.  Spectral reflectance based indices for soil organic carbon quantification , 2008 .

[32]  J. Qu,et al.  NMDI: A normalized multi‐band drought index for monitoring soil and vegetation moisture with satellite remote sensing , 2007 .

[33]  M. Cho,et al.  A new technique for extracting the red edge position from hyperspectral data: The linear extrapolation method , 2006 .

[34]  Carl E. Rasmussen,et al.  Gaussian Processes for Machine Learning (Adaptive Computation and Machine Learning) , 2005 .

[35]  J. Dash,et al.  The MERIS terrestrial chlorophyll index , 2004 .

[36]  D. Sims,et al.  Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages , 2002 .

[37]  J. Peñuelas,et al.  Remote sensing of nitrogen and lignin in Mediterranean vegetation from AVIRIS data: Decomposing biochemical from structural signals , 2002 .

[38]  John R. Miller,et al.  Integrated narrow-band vegetation indices for prediction of crop chlorophyll content for application to precision agriculture , 2002 .

[39]  S. Wold,et al.  PLS-regression: a basic tool of chemometrics , 2001 .

[40]  P.J. Zarco-Tejada,et al.  Modeling canopy water content for carbon estimates from MODIS data at land EOS validation sites , 2001, IGARSS 2001. Scanning the Present and Resolving the Future. Proceedings. IEEE 2001 International Geoscience and Remote Sensing Symposium (Cat. No.01CH37217).

[41]  N. Broge,et al.  Comparing prediction power and stability of broadband and hyperspectral vegetation indices for estimation of green leaf area index and canopy chlorophyll density , 2001 .

[42]  Moon S. Kim,et al.  Estimating Corn Leaf Chlorophyll Concentration from Leaf and Canopy Reflectance , 2000 .

[43]  G. A. Blackburn,et al.  Quantifying Chlorophylls and Caroteniods at Leaf and Canopy Scales: An Evaluation of Some Hyperspectral Approaches , 1998 .

[44]  E. J. Milton,et al.  Processing of High Spectral Resolution Reflectance Data for the Retrieval of Canopy Water Content Information , 1998 .

[45]  J. Peñuelas,et al.  Estimation of plant water concentration by the reflectance Water Index WI (R900/R970) , 1997 .

[46]  A. Huete,et al.  A comparison of vegetation indices over a global set of TM images for EOS-MODIS , 1997 .

[47]  A. Gitelson,et al.  Use of a green channel in remote sensing of global vegetation from EOS- MODIS , 1996 .

[48]  B. Gao NDWI—A normalized difference water index for remote sensing of vegetation liquid water from space , 1996 .

[49]  G. Rondeaux,et al.  Optimization of soil-adjusted vegetation indices , 1996 .

[50]  R. G. Smith,et al.  Forecasting wheat yield in a Mediterranean-type environment from the NOAA satellite , 1995 .

[51]  A. Huete,et al.  A Modified Soil Adjusted Vegetation Index , 1994 .

[52]  A. Gitelson,et al.  Quantitative estimation of chlorophyll-a using reflectance spectra : experiments with autumn chestnut and maple leaves , 1994 .

[53]  G. Carter Ratios of leaf reflectances in narrow wavebands as indicators of plant stress , 1994 .

[54]  J. Peñuelas,et al.  The reflectance at the 950–970 nm region as an indicator of plant water status , 1993 .

[55]  D. M. Moss,et al.  Red edge spectral measurements from sugar maple leaves , 1993 .

[56]  C. Field,et al.  A narrow-waveband spectral index that tracks diurnal changes in photosynthetic efficiency , 1992 .

[57]  B. Rock,et al.  Detection of changes in leaf water content using Near- and Middle-Infrared reflectances , 1989 .

[58]  J. Gower,et al.  Observations of in situ fluorescence of chlorophyll-a in Saanich Inlet , 1980 .

[59]  C. Tucker Red and photographic infrared linear combinations for monitoring vegetation , 1979 .

[60]  C. Jordan Derivation of leaf-area index from quality of light on the forest floor , 1969 .

[61]  Gengxing Zhao,et al.  Soil salinity inversion based on differentiated fusion of satellite image and ground spectra , 2021, Int. J. Appl. Earth Obs. Geoinformation.

[62]  M. Hardisky The Influence of Soil Salinity, Growth Form, and Leaf Moisture on-the Spectral Radiance of Spartina alterniflora Canopies , 2008 .

[63]  Yuri A. Gritz,et al.  Relationships between leaf chlorophyll content and spectral reflectance and algorithms for non-destructive chlorophyll assessment in higher plant leaves. , 2003, Journal of plant physiology.

[64]  T. S. Prasad,et al.  New hyperspectral vegetation characterization parameters , 2001 .

[65]  L. Breiman Random Forests , 2001, Machine Learning.

[66]  B. Datt,et al.  Visible/near infrared reflectance and chlorophyll content in Eucalyptus leaves , 1999 .

[67]  B. Kowalski,et al.  Partial least-squares regression: a tutorial , 1986 .