Crop Water Content of Winter Wheat Revealed with Sentinel-1 and Sentinel-2 Imagery

This study aims to efficiently estimate the crop water content of winter wheat using high spatial and temporal resolution satellite-based imagery. Synthetic-aperture radar (SAR) data collected by the Sentinel-1 satellite and optical imagery from the Sentinel-2 satellite was used to create inversion models for winter wheat crop water content, respectively. In the Sentinel-1 approach, several enhanced radar indices were constructed by Sentinel-1 backscatter coefficient of imagery, and selected the one that was most sensitive to soil water content as the input parameter of a water cloud model. Finally, a water content inversion model for winter wheat crop was established. In the Sentinel-2 approach, the gray relational analysis was used for several optical vegetation indices constructed by Sentinel-2 spectral feature of imagery, and three vegetation indices were selected for multiple linear regression modeling to retrieve the wheat crop water content. 58 ground samples were utilized in modeling and verification. The water content inversion model based on Sentinel-2 optical images exhibited higher verification accuracy (R = 0.632, RMSE = 0.021 and nRMSE = 19.65%) than the inversion model based on Sentinel-1 SAR (R = 0.433, RMSE = 0.026 and nRMSE = 21.24%). This study provides a reference for estimating the water content of wheat crops using data from the Sentinel series of satellites.

[1]  Jianlong Li,et al.  Application of a normalized difference impervious index (NDII) to extract urban impervious surface features based on Landsat TM images , 2015 .

[2]  Chunjiang Zhao,et al.  Estimation of soil moisture from multi-polarized SAR data over wheat coverage areas , 2012, 2012 First International Conference on Agro- Geoinformatics (Agro-Geoinformatics).

[3]  Zhongxin Chen,et al.  Research advances of SAR remote sensing for agriculture applications: A review , 2019, Journal of Integrative Agriculture.

[4]  Deng Ju-Long,et al.  Control problems of grey systems , 1982 .

[5]  J. Qu,et al.  Forest fire detection using the normalized multi-band drought index (NMDI) with satellite measurements , 2008 .

[6]  Wenjiang Huang,et al.  [Using canopy hyperspectral ratio index to retrieve relative water content of wheat under yellow rust stress]. , 2010, Guang pu xue yu guang pu fen xi = Guang pu.

[7]  Roberta E. Martin,et al.  Remote measurement of canopy water content in giant sequoias (Sequoiadendron giganteum) during drought , 2017, Forest Ecology and Management.

[8]  Antonino Maltese,et al.  Investigating the Relationship between X-Band SAR Data from COSMO-SkyMed Satellite and NDVI for LAI Detection , 2013, Remote. Sens..

[9]  Yubin Lan,et al.  Combined Multi-Temporal Optical and Radar Parameters for Estimating LAI and Biomass in Winter Wheat Using HJ and RADARSAR-2 Data , 2015, Remote. Sens..

[10]  R. Sahoo,et al.  Comparison of different uni- and multi-variate techniques for monitoring leaf water status as an indicator of water-deficit stress in wheat through spectroscopy , 2017 .

[11]  Jakob van Zyl,et al.  Estimation of canopy water content in Konza Prairie grasslands using synthetic aperture radar measurements during FIFE , 1995 .

[12]  Heather McNairn,et al.  Using multi-polarization C- and L-band synthetic aperture radar to estimate biomass and soil moisture of wheat fields , 2017, Int. J. Appl. Earth Obs. Geoinformation.

[13]  R. Fensholt,et al.  Evaluating EO-based canopy water stress from seasonally detrended NDVI and SIWSI with modeled evapotranspiration in the Senegal River Basin , 2015 .

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

[15]  R. G. Brown,et al.  Estimating Leaf Water Content by Reflectance Measurements1 , 1971 .

[16]  Jan G. P. W. Clevers,et al.  Using hyperspectral remote sensing data for retrieving canopy water content , 2009, 2009 First Workshop on Hyperspectral Image and Signal Processing: Evolution in Remote Sensing.

[17]  Alfredo Huete,et al.  From AVHRR-NDVI to MODIS-EVI: Advances in vegetation index research , 2003 .

[18]  Susan C. Steele-Dunne,et al.  Using Diurnal Variation in Backscatter to Detect Vegetation Water Stress , 2012, IEEE Transactions on Geoscience and Remote Sensing.

[19]  Rabi N. Sahoo,et al.  Application of thermal imaging and hyperspectral remote sensing for crop water deficit stress monitoring , 2019, Geocarto International.

[20]  François Anctil,et al.  Thermal‐water stress index from satellite images , 2006 .

[21]  Qingyan Meng,et al.  A fusion approach of the improved Dubois model and best canopy water retrieval models to retrieve soil moisture through all maize growth stages from Radarsat-2 and Landsat-8 data , 2016, Environmental Earth Sciences.

[22]  Irena Hajnsek,et al.  Investigation of SMAP Fusion Algorithms With Airborne Active and Passive L-Band Microwave Remote Sensing , 2016, IEEE Transactions on Geoscience and Remote Sensing.

[23]  R. Fensholt,et al.  Derivation of a shortwave infrared water stress index from MODIS near- and shortwave infrared data in a semiarid environment , 2003 .

[24]  Nektarios Chrysoulakis,et al.  Comparison of physically and image based atmospheric correction methods for Sentinel-2 satellite imagery , 2016, International Conference on Remote Sensing and Geoinformation of Environment.

[25]  David Riaño,et al.  Detection of diurnal variation in orchard canopy water content using MODIS/ASTER airborne simulator (MASTER) data , 2013 .

[26]  Wolfram Mauser,et al.  Fitted PROSAIL Parameterization of Leaf Inclinations, Water Content and Brown Pigment Content for Winter Wheat and Maize Canopies , 2019, Remote. Sens..

[27]  Pei Leng,et al.  [Estimation of vegetation canopy water content using Hyperion hyperspectral data]. , 2013, Guang pu xue yu guang pu fen xi = Guang pu.

[28]  George P. Petropoulos,et al.  Surface soil moisture retrievals over partially vegetated areas from the synergy of Sentinel-1 and Landsat 8 data using a modified water-cloud model , 2018, Int. J. Appl. Earth Obs. Geoinformation.

[29]  Guido Lemoine,et al.  Parcel-Based Crop Classification in Ukraine Using Landsat-8 Data and Sentinel-1A Data , 2016, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[30]  Son V. Nghiem,et al.  Estimating Live Fuel Moisture Using SMAP L-Band Radiometer Soil Moisture for Southern California, USA , 2019, Remote. Sens..

[31]  Sabrina Esch,et al.  Soil moisture index from ERS-SAR and its application to the analysis of spatial patterns in agricultural areas , 2018 .

[32]  Qingyan Meng,et al.  Combining of the H/A/Alpha and Freeman–Durden Polarization Decomposition Methods for Soil Moisture Retrieval from Full-Polarization Radarsat-2 Data , 2018, Advances in Meteorology.

[33]  K. Ruddick,et al.  Advantages of high quality SWIR bands for ocean colour processing: Examples from Landsat-8 , 2015 .

[34]  Mahta Moghaddam,et al.  Estimation of crown and stem water content and biomass of boreal forest using polarimetric SAR imagery , 2000, IEEE Trans. Geosci. Remote. Sens..

[35]  Guijun Yang,et al.  Estimating wheat biomass from GF-3 data and a polarized water cloud model , 2018, Remote Sensing Letters.

[36]  Jun Wen,et al.  Derivation of Vegetation Optical Depth and Water Content in the Source Region of the Yellow River using the FY-3B Microwave Data , 2019, Remote. Sens..

[37]  J. Townshend,et al.  NDVI-derived land cover classifications at a global scale , 1994 .

[38]  J. Clevers,et al.  Combined use of optical and microwave remote sensing data for crop growth monitoring , 1996 .

[39]  C. Atzberger,et al.  Spatially constrained inversion of radiative transfer models for improved LAI mapping from future Sentinel-2 imagery , 2012 .

[40]  Mehrez Zribi,et al.  Calibration of the Water Cloud Model at C-Band for Winter Crop Fields and Grasslands , 2017, Remote. Sens..

[41]  Susan C. Steele-Dunne,et al.  Impact of Diurnal Variation in Vegetation Water Content on Radar Backscatter From Maize During Water Stress , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[42]  Dara Entekhabi,et al.  Vegetation optical depth and scattering albedo retrieval using time series of dual-polarized L-band radiometer observations , 2016 .

[43]  Zhiyong Wang,et al.  Inversion of Rice Biophysical Parameters Using Simulated Compact Polarimetric SAR C-Band Data , 2018, Sensors.

[44]  S. Idso,et al.  Normalizing the stress-degree-day parameter for environmental variability☆ , 1981 .

[45]  Thomas J. Jackson,et al.  Retrieval of Wheat Growth Parameters With Radar Vegetation Indices , 2014, IEEE Geoscience and Remote Sensing Letters.

[46]  S. Ustin,et al.  Estimating Vegetation Water content with Hyperspectral data for different Canopy scenarios: Relationships between AVIRIS and MODIS Indexes , 2006 .

[47]  S. Tarantola,et al.  Detecting vegetation leaf water content using reflectance in the optical domain , 2001 .