Improving Biomass and Grain Yield Prediction of Wheat Genotypes on Sodic Soil Using Integrated High-Resolution Multispectral, Hyperspectral, 3D Point Cloud, and Machine Learning Techniques

Sodic soils adversely affect crop production over extensive areas of rain-fed cropping worldwide, with particularly large areas in Australia. Crop phenotyping may assist in identifying cultivars tolerant to soil sodicity. However, studies to identify the most appropriate traits and reliable tools to assist crop phenotyping on sodic soil are limited. Hence, this study evaluated the ability of multispectral, hyperspectral, 3D point cloud, and machine learning techniques to improve estimation of biomass and grain yield of wheat genotypes grown on a moderately sodic (MS) and highly sodic (HS) soil sites in northeastern Australia. While a number of studies have reported using different remote sensing approaches and crop traits to quantify crop growth, stress, and yield variation, studies are limited using the combination of these techniques including machine learning to improve estimation of genotypic biomass and yield, especially in constrained sodic soil environments. At close to flowering, unmanned aerial vehicle (UAV) and ground-based proximal sensing was used to obtain remote and/or proximal sensing data, while biomass yield and crop heights were also manually measured in the field. Grain yield was machine-harvested at maturity. UAV remote and/or proximal sensing-derived spectral vegetation indices (VIs), such as normalized difference vegetation index, optimized soil adjusted vegetation index, and enhanced vegetation index and crop height were closely corresponded to wheat genotypic biomass and grain yields. UAV multispectral VIs more closely associated with biomass and grain yields compared to proximal sensing data. The red-green-blue (RGB) 3D point cloud technique was effective in determining crop height, which was slightly better correlated with genotypic biomass and grain yield than ground-measured crop height data. These remote sensing-derived crop traits (VIs and crop height) and wheat biomass and grain yields were further simulated using machine learning algorithms (multitarget linear regression, support vector machine regression, Gaussian process regression, and artificial neural network) with different kernels to improve estimation of biomass and grain yield. The artificial neural network predicted biomass yield (R2 = 0.89; RMSE = 34.8 g/m2 for the MS and R2 = 0.82; RMSE = 26.4 g/m2 for the HS site) and grain yield (R2 = 0.88; RMSE = 11.8 g/m2 for the MS and R2 = 0.74; RMSE = 16.1 g/m2 for the HS site) with slightly less error than the others. Wheat genotypes Mitch, Corack, Mace, Trojan, Lancer, and Bremer were identified as more tolerant to sodic soil constraints than Emu Rock, Janz, Flanker, and Gladius. The study improves our ability to select appropriate traits and techniques in accurate estimation of wheat genotypic biomass and grain yields on sodic soils. This will also assist farmers in identifying cultivars tolerant to sodic soil constraints.

[1]  A. Apan,et al.  UAV-Thermal imaging and agglomerative hierarchical clustering techniques to evaluate and rank physiological performance of wheat genotypes on sodic soil , 2021 .

[2]  Salah Sukkarieh,et al.  Machine learning approaches for crop yield prediction and nitrogen status estimation in precision agriculture: A review , 2018, Comput. Electron. Agric..

[3]  Anil Rai,et al.  Small area estimation of crop yield using remote sensing satellite data , 2002 .

[4]  Alper Adak,et al.  Temporal Vegetation Indices and Plant Height from Remotely Sensed Imagery Can Predict Grain Yield and Flowering Time Breeding Value in Maize via Machine Learning Regression , 2021, Remote. Sens..

[5]  K. Ennouri,et al.  Multiple linear regression and artificial neural networks for delta-endotoxin and protease yields modelling of Bacillus thuringiensis , 2017, 3 Biotech.

[6]  Z. Shi,et al.  Mapping Horizontal and Vertical Spatial Variability of Soil Salinity in Reclaimed Areas , 2016 .

[7]  Dimitrios Skarlatos,et al.  Investigating Correlation among NDVI Index Derived by Unmanned Aerial Vehicle Photography and Grain Yield under Late Drought Stress Conditions , 2015 .

[8]  Xiaodong Yang,et al.  Modeling maize above-ground biomass based on machine learning approaches using UAV remote-sensing data , 2019, Plant Methods.

[9]  Yang Song,et al.  Winter Wheat Canopy Height Extraction from UAV-Based Point Cloud Data with a Moving Cuboid Filter , 2019, Remote. Sens..

[10]  Guijun Yang,et al.  A rapid monitoring of NDVI across the wheat growth cycle for grain yield prediction using a multi-spectral UAV platform. , 2019, Plant science : an international journal of experimental plant biology.

[11]  K. Sudduth,et al.  Yield estimation in cotton using UAV-based multi-sensor imagery , 2020 .

[12]  Jing Liu,et al.  Neural networks for setting target corn yields , 2000 .

[13]  A. Pellegrinelli,et al.  Multispectral UAV monitoring of submerged seaweed in shallow water , 2019, Applied Geomatics.

[14]  F. Baret,et al.  High-Throughput Phenotyping of Plant Height: Comparing Unmanned Aerial Vehicles and Ground LiDAR Estimates , 2017, Front. Plant Sci..

[15]  Sandeep Dhakal,et al.  Evaluation of Temperature-Based Empirical Models and Machine Learning Techniques to Estimate Daily Global Solar Radiation at Biratnagar Airport, Nepal , 2020 .

[16]  Simon Bennertz,et al.  Estimating Biomass of Barley Using Crop Surface Models (CSMs) Derived from UAV-Based RGB Imaging , 2014, Remote. Sens..

[17]  R. Dalal,et al.  Genetic Diversity in Barley and Wheat for Tolerance to Soil Constraints , 2016 .

[18]  Lei Guo,et al.  Wheat yellow rust monitoring by learning from multispectral UAV aerial imagery , 2018, Comput. Electron. Agric..

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

[20]  H. A. Sanjay,et al.  A Parameter Based Customized Artificial Neural Network Model for Crop Yield Prediction , 2016 .

[21]  A. Alvino,et al.  Use of proximal sensing and vegetation indexes to detect the inefficient spatial allocation of drip irrigation in a spot area of tomato field crop , 2015, Precision Agriculture.

[22]  Xiaodong Yang,et al.  Estimation of the Yield and Plant Height of Winter Wheat Using UAV-Based Hyperspectral Images , 2020, Sensors.

[23]  Shusen Wang,et al.  Crop yield forecasting on the Canadian Prairies using MODIS NDVI data , 2011 .

[24]  Borys Stoew,et al.  Non-destructive Phenotypic Analysis of Early Stage Tree Seedling Growth Using an Automated Stereovision Imaging Method , 2016, Front. Plant Sci..

[25]  G. Menexes,et al.  Assessment of Vegetation Indices Derived by UAV Imagery for Durum Wheat Phenotyping under a Water Limited and Heat Stressed Mediterranean Environment , 2017, Front. Plant Sci..

[26]  Yanjie Wang,et al.  Estimation of Winter Wheat Above-Ground Biomass Using Unmanned Aerial Vehicle-Based Snapshot Hyperspectral Sensor and Crop Height Improved Models , 2017, Remote. Sens..

[27]  J. R. Rodríguez-Pérez,et al.  Field Spectroscopy: A Non-Destructive Technique for Estimating Water Status in Vineyards , 2019, Agronomy.

[28]  Nick Z. Zacharis,et al.  Predicting Student Academic Performance in Blended Learning Using Artificial Neural Networks , 2016 .

[29]  Bruno Basso,et al.  Cultivar discrimination at different site elevations with remotely sensed vegetation indices , 2010 .

[30]  Dong Jiang,et al.  An artificial neural network model for estimating crop yields using remotely sensed information , 2004 .

[31]  C. Justice,et al.  Development of vegetation and soil indices for MODIS-EOS , 1994 .

[32]  Weixing Cao,et al.  Predicting grain yield in rice using multi-temporal vegetation indices from UAV-based multispectral and digital imagery , 2017 .

[33]  Jan U.H. Eitel,et al.  Proximal NDVI derived phenology improves in-season predictions of wheat quantity and quality , 2016 .

[34]  A. Apan,et al.  Evaluation of water status of wheat genotypes to aid prediction of yield on sodic soils using UAV-thermal imaging and machine learning , 2021 .

[35]  U. Rathnayake,et al.  Artificial Neural Network to Estimate the Paddy Yield Prediction Using Climatic Data , 2020, Mathematical Problems in Engineering.

[36]  Ulrich Schurr,et al.  Future scenarios for plant phenotyping. , 2013, Annual review of plant biology.

[37]  S. Chapman,et al.  Dynamic monitoring of NDVI in wheat agronomy and breeding trials using an unmanned aerial vehicle , 2017 .

[38]  Armando Apan,et al.  Detection of phenoxy herbicide dosage in cotton crops through the analysis of hyperspectral data , 2017 .

[39]  Daniel Gianola,et al.  Application of support vector regression to genome-assisted prediction of quantitative traits , 2011, Theoretical and Applied Genetics.

[40]  W. Johannsen,et al.  The Genotype Conception of Heredity , 1911, The American Naturalist.

[41]  Lutz Plümer,et al.  Low-Cost 3D Systems: Suitable Tools for Plant Phenotyping , 2014, Sensors.

[42]  A. Kayabasi An Application of ANN Trained by ABC Algorithm for Classification of Wheat Grains , 2018 .

[43]  Armando Apan,et al.  Improving estimation of in-season crop water use and health of wheat genotypes on sodic soils using spatial interpolation techniques and multi-component metrics , 2021 .

[44]  Liyuan Zhang,et al.  Maize Canopy Temperature Extracted From UAV Thermal and RGB Imagery and Its Application in Water Stress Monitoring , 2019, Front. Plant Sci..

[45]  Christopher Boomsma,et al.  Maize grain yield responses to plant height variability resulting from crop rotation and tillage system in a long-term experiment , 2010 .

[46]  Sami Ekici,et al.  Comparison of different regression models to estimate fault location on hybrid power systems , 2019 .

[47]  Hao Yang,et al.  Unmanned Aerial Vehicle Remote Sensing for Field-Based Crop Phenotyping: Current Status and Perspectives , 2017, Front. Plant Sci..

[48]  James Patrick Underwood,et al.  Image Based Mango Fruit Detection, Localisation and Yield Estimation Using Multiple View Geometry , 2016, Sensors.

[49]  Luís Pádua,et al.  UAS, sensors, and data processing in agroforestry: a review towards practical applications , 2017 .

[50]  Armando Apan,et al.  Hyperspectral sensing to detect the impact of herbicide drift on cotton growth and yield , 2016 .

[51]  R. Barnes,et al.  Standard Normal Variate Transformation and De-Trending of Near-Infrared Diffuse Reflectance Spectra , 1989 .

[52]  M. Mkhabela,et al.  Early maize yield forecasting in the four agro-ecological regions of Swaziland using NDVI data derived from NOAA's-AVHRR , 2005 .

[53]  S. Samarasinghe,et al.  Prediction of Wheat Production Using Artificial Neural Networks and Investigating Indirect Factors Affecting It: Case Study in Canterbury Province, New Zealand , 2015 .

[54]  Urs Schmidhalter,et al.  Digital Counts of Maize Plants by Unmanned Aerial Vehicles (UAVs) , 2017, Remote. Sens..

[55]  Zuzana Lhotáková,et al.  Comparison of Reflectance Measurements Acquired with a Contact Probe and an Integration Sphere: Implications for the Spectral Properties of Vegetation at a Leaf Level , 2016, Sensors.

[56]  Yuxin Miao,et al.  Identifying important factors influencing corn yield and grain quality variability using artificial neural networks , 2006, Precision Agriculture.

[57]  Simon Bennertz,et al.  Combining UAV-based plant height from crop surface models, visible, and near infrared vegetation indices for biomass monitoring in barley , 2015, Int. J. Appl. Earth Obs. Geoinformation.

[58]  S. Sathiya Keerthi,et al.  Improvements to the SMO algorithm for SVM regression , 2000, IEEE Trans. Neural Networks Learn. Syst..

[59]  A. Alvino,et al.  Detection of Spatial and Temporal Variability of Wheat Cultivars by High-Resolution Vegetation Indices , 2019, Agronomy.

[60]  Stuart R. Phinn,et al.  Estimating tree‐cover change in Australia: challenges of using the MODIS vegetation index product , 2009 .

[61]  Arnold Bregt,et al.  Geosensors to Support Crop Production: Current Applications and User Requirements , 2011, Sensors.

[62]  Jose A. Jiménez-Berni,et al.  High Throughput Determination of Plant Height, Ground Cover, and Above-Ground Biomass in Wheat with LiDAR , 2018, Front. Plant Sci..

[63]  Rachel R. Fern,et al.  Suitability of NDVI and OSAVI as estimators of green biomass and coverage in a semi-arid rangeland , 2018, Ecological Indicators.

[64]  Gustavo A. Slafer,et al.  Can wheat yield be assessed by early measurements of Normalized Difference Vegetation Index , 2007 .

[65]  J. A. Schell,et al.  Monitoring vegetation systems in the great plains with ERTS , 1973 .

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

[67]  Marzieh Mokarram,et al.  Prediction of biological and grain yield of barley using multiple regression and artificial neural network models , 2016 .

[68]  Marco Dubbini,et al.  Evaluating Multispectral Images and Vegetation Indices for Precision Farming Applications from UAV Images , 2015, Remote. Sens..

[69]  Ana Reyes-Menendez,et al.  Mapping multispectral Digital Images using a Cloud Computing software: applications from UAV images , 2019, Heliyon.