Analysis of L-Band SAR Data for Soil Moisture Estimations over Agricultural Areas in the Tropics

Zribi, Mehrez; Sekhar, M.; Bousbih, Safa; Bitar, Ahmad Al; Tomer, Sat Kumar; Baghdadi, Nicolas; Bandyopadhyay, Samir Kumar

doi:10.3390/rs11091122

Cited by 45 publications

(23 citation statements)

References 72 publications

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“…The laser profilometer was considered a benchmark for 2D roughness measurements for several reasons: (1) its vertical accuracy is high; (2) its nadir‐looking geometry avoids occlusions, and; (3) although it measures 2D profiles and not 3D surfaces, it has been the standard technique to characterize surface roughness for different applications for the last decades (Oh et al, ; Helming et al, ; Davidson et al, ; Darboux and Huang, ; Callens et al, ; Baghdadi et al, ; Verhoest et al, ) and is still used at present (El Hajj et al, ; Zribi et al, ). Thus, it can be considered a state of the art technology in the field of surface roughness measurement.…”

Section: Methodsmentioning

confidence: 99%

“…Profilometer data processing was done in three steps: (1) correction of the aluminum beam bending using a lab determined TLS AND SFM FOR QUANTIFYING SURFACE ROUGHNESS OVER AGRICULTURAL SOILS parabolic function, (2) outlier filtering by deleting and interpolating records larger than a threshold (i.e., 2 cm) with the previous and following records (to filter out vegetation elements eventually present on the soil surface), and (3) terrain slope correction (i.e., profile detrending) subtracting the linear trend observed in the data, if any. The laser profilometer was considered a benchmark for 2D roughness measurements for several reasons: (1) its vertical accuracy is high; (2) its nadir-looking geometry avoids occlusions, and; (3) although it measures 2D profiles and not 3D surfaces, it has been the standard technique to characterize surface roughness for different applications for the last decades (Oh et al, 1992;Helming et al, 1998;Davidson et al, 2000;Darboux and Huang, 2003;Callens et al, 2006;Baghdadi et al, 2008;Verhoest et al, 2008) and is still used at present (El Hajj et al, 2019;Zribi et al, 2019). Thus, it can be considered a state of the art technology in the field of surface roughness measurement.…”

Section: Measuring Techniquesmentioning

confidence: 99%

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Evaluation of Terrestrial Laser Scanner and Structure from Motion photogrammetry techniques for quantifying soil surface roughness parameters over agricultural soils

Martinez‐Agirre

Álvarez‐Mozos

Milenković

et al. 2019

Earth Surf Processes Landf

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The surface roughness of agricultural soils is mainly related to the type of tillage performed, typically consisting of oriented and random components. Traditionally, soil surface roughness (SSR) characterization has been difficult due to its high spatial variability and the sensitivity of roughness parameters to the characteristics of the instruments, including its measurement scale. Recent advances in surveying have greatly improved the spatial resolution, extent, and availability of surface elevation datasets. However, it is still unknown how new roughness measurements relates with the conventional roughness measurements such as 2D profiles acquired by laser profilometers. The objective of this study was to evaluate the suitability of Terrestrial Laser Scanner (TLS) and Structure from Motion (SfM) photogrammetry techniques for quantifying SSR over different agricultural soils. With this aim, an experiment was carried out in three plots (5 × 5 m) representing different roughness conditions, where TLS and SfM photogrammetry measurements were co‐registered with 2D profiles obtained using a laser profilometer. Differences between new and conventional roughness measurement techniques were evaluated visually and quantitatively using regression analysis and comparing the values of six different roughness parameters. TLS and SfM photogrammetry measurements were further compared by evaluating multi‐directional roughness parameters and analyzing corresponding Digital Elevation Models. The results obtained demonstrate the ability of both TLS and SfM photogrammetry techniques to measure 3D SSR over agricultural soils. However, profiles obtained with both techniques (especially SfM photogrammetry) showed a loss of high‐frequency elevation information that affected the values of some parameters (e.g. initial slope of the autocorrelation function, peak frequency and tortuosity). Nevertheless, both TLS and SfM photogrammetry provide a massive amount of 3D information that enables a detailed analysis of surface roughness, which is relevant for multiple applications, such as those focused in hydrological and soil erosion processes and microwave scattering. © 2019 John Wiley & Sons, Ltd.

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Section: Methodsmentioning

confidence: 99%

Section: Measuring Techniquesmentioning

confidence: 99%

Evaluation of Terrestrial Laser Scanner and Structure from Motion photogrammetry techniques for quantifying soil surface roughness parameters over agricultural soils

Martinez‐Agirre

Álvarez‐Mozos

Milenković

et al. 2019

Earth Surf Processes Landf

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“…In a study, Zribi et al [29] have applied Water Cloud Model (WCM) on L-band PALSAR/ALOS-2 satellite data to estimate soil moisture in a tropical agricultural area under dense vegetation cover conditions. Yang et al [30] have used the fully polarimetric C-band Radarsat-2 SAR data for soil moisture mapping in Juyanze Basin, China.…”

Section: Introductionmentioning

confidence: 99%

Estimation of Soil Moisture Applying Modified Dubois Model to Sentinel-1; A Regional Study from Central India

et al. 2020

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Surface soil moisture has a wide application in climate change, agronomy, water resources, and in many other domain of science and engineering. Measurement of soil moisture at high spatial and temporal resolution at regional and global scale is needed for the prediction of flood, drought, planning and management of agricultural productivity to ensure food security. Recent advancement in microwave remote sensing, especially after the launch of Sentinel operational satellites has enabled the scientific community to estimate soil moisture at higher spatial and temporal resolution with greater accuracy. This study evaluates the potential of Sentinel-1A satellite images to estimate soil moisture in a semi-arid region. Exactly at the time when satellite passes over the study area, we have collected soil samples at 37 different locations and measured the soil moisture from 5 cm below the ground surface using ML3 theta probe. We processed the soil samples in laboratory to obtain volumetric soil moisture using the oven dry method. We found soil moisture measured from calibrated theta probe and oven dry method are in good agreement with Root Mean Square Error (RMSE) 0.025 m 3 /m 3 and coefficient of determination (R 2 ) 0.85. We then processed Sentinel-1A images and applied modified Dubois model to calculate relative permittivity of the soil from the backscatter values ( σ ∘ ). The volumetric soil moisture at each pixel is then calculated by applying the universal Topp’s model. Finally, we masked the pixels whose Normalised Difference Vegetation Index (NDVI) value is greater than 0.4 to generate soil moisture map as per the Dubois NDVI criterion. Our modelled soil moisture accord with the measured values with RMSE = 0.035 and R 2 = 0.75. We found a small bias in the modelled soil moisture ( 0.02 m 3 / m 3 ). However, this has reduced significantly ( 0.001 m 3 / m 3 ) after applying a bias correction based on Cumulative Distribution Function (CDF) matching. Our approach provides a first-order estimate of soil moisture from Sentinel-1A images in sparsely vegetated agricultural land.

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“…Over the last four decades, considerable research efforts have been devoted to soil moisture estimation by means of synthetic aperture radar (SAR) and proved the potential of SAR data at L, C, and X bands for estimating SSM over bare and vegetated soils [2], [3]. The use of physical models (IEM, AIEM), semi-empirical models (Oh, Dubois, and Shi) [4], decomposition theorems (Freeman-Durden, Yamaguchi, and Cloude-Pottier) [5], [6], [7], change detection techniques [8], [9], [10], and statistics-based methods [11], [12], [13] applied to multiple SAR observations have improved the capability to obtain SSM information at high spatial resolution (less than 10 m).…”

mentioning

confidence: 99%

“…IEM and AIEM) scattering models could be used to estimate the SSM from the remaining ground scattering components [19], [20]. Notably, the complexity of the volume scattering model [4], [5] and the number of modeled scattering components are important aspects in the description of the scattering properties of this type of scenes. Another strategy to take into account the presence of vegetation on the ground consists in adopting statistical approaches, for instance based on Bayes theorem or on machine learning methods [11], [12], [21].…”

mentioning

confidence: 99%

Contribution of Polarimetry and Multi-Incidence to Soil Moisture Estimation Over Agricultural Fields Based on Time Series of L-Band SAR Data

Shi

López-Sánchez

et al. 2021

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Analysis of L-Band SAR Data for Soil Moisture Estimations over Agricultural Areas in the Tropics

Cited by 45 publications

References 72 publications

Evaluation of Terrestrial Laser Scanner and Structure from Motion photogrammetry techniques for quantifying soil surface roughness parameters over agricultural soils

Evaluation of Terrestrial Laser Scanner and Structure from Motion photogrammetry techniques for quantifying soil surface roughness parameters over agricultural soils

Estimation of Soil Moisture Applying Modified Dubois Model to Sentinel-1; A Regional Study from Central India

Contribution of Polarimetry and Multi-Incidence to Soil Moisture Estimation Over Agricultural Fields Based on Time Series of L-Band SAR Data

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