Effects of Spatial Sampling Interval on Roughness Parameters and Microwave Backscatter over Agricultural Soil Surfaces

Barber, M.; Grings, F.; Álvarez‐Mozos, Jesús; Piscitelli, M.; Perna, P.; Karszenbaum, H.

doi:10.3390/rs8060458

Cited by 14 publications

(16 citation statements)

References 27 publications

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“…Regarding the influence of small-scale components, the results demonstrate that eliminating these small-scale roughness components from the profiles caused a strong variation in the values of horizontal parameters, while vertical ones were more insensitive. This is in agreement with Barber et al [30] who observed that when the sampling interval increased, s decreased slightly and l increased causing the separability between different roughness classes to decrease. The results also confirm that l values did not stabilize with long profiles, but showed rather an increase in their variability [19], [26].…”

Section: Discussionsupporting

confidence: 93%

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Influence of Surface Roughness Measurement Scale on Radar Backscattering in Different Agricultural Soils

Martinez‐Agirre

Álvarez‐Mozos

Lievens

et al. 2017

IEEE Trans. Geosci. Remote Sensing

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Soil surface roughness strongly affects the scattering 1 of microwaves on the soil surface and determines the backscat-2 tering coefficient (σ 0) observed by radar sensors. Previous 3 studies have shown important scale issues that compromise the 4 measurement and parameterization of roughness especially in 5 agricultural soils. The objective of this paper was to determine 6 the roughness scales involved in the backscattering process over 7 agricultural soils. With this aim, a database of 132 5-m profiles 8 taken on agricultural soils with different tillage conditions was 9 used. These measurements were acquired coinciding with a 10 series of ENVISAT/ASAR observations. Roughness profiles were 11 processed considering three different scaling issues: 1) influence 12 of measurement range; 2) influence of low-frequency rough-13 ness components; and 3) influence of high-frequency roughness 14 components. For each of these issues, eight different roughness 15 parameters were computed and the following aspects were eval-16 uated: 1) roughness parameters values; 2) correlation with σ 0 ; 17 and 3) goodness-of-fit of the Oh model. Most parameters had a 18 significant correlation with σ 0 especially the fractal dimension, 19 the peak frequency, and the initial slope of the autocorrela-20 tion function. These parameters had higher correlations than 21 classical parameters such as the standard deviation of surface 22 heights or the correlation length. Very small differences were 23 observed when longer than 1-m profiles were used as well as when 24 small-scale roughness components (<5 cm) or large-scale rough-25 ness components (>100 cm) were disregarded. In conclusion, 26 the medium-frequency roughness components (scale of 5-100 cm) 27 seem to be the most influential scales in the radar backscattering 28 process on agricultural soils.

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Section: Discussionsupporting

confidence: 93%

“…Barber et al [30] evaluated the influence of sampling interval on the SSR statistics over agricultural soils and observed that class differences were reduced as the measurement interval increased. They also recommended intervals of 15 and 5 mm for L-and C-bands, respectively.…”

mentioning

confidence: 99%

Influence of Surface Roughness Measurement Scale on Radar Backscattering in Different Agricultural Soils

Martinez‐Agirre

Álvarez‐Mozos

Lievens

et al. 2017

IEEE Trans. Geosci. Remote Sensing

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“…The dense point cloud was then rotated to the true X, Y, and Z directions using markers that were manually placed on images showing the measuring tapes and assuming Z = 0 for all points (i.e., models then display the surface elevation relative to the plain defined by the two measuring tapes). In the third step, the DEM and the ortho-mosaic were processed with a pixel spacing of 0.2 cm, of 0.1 cm respectively, meeting the sampling interval for C-Band data (0.5 cm) recommended by [44]. Table 2 reports the accuracies of the processed ground-based DEMs in X, Y, and Z direction.…”

Section: Fieldwork and Samplingmentioning

confidence: 99%

Surface Roughness Estimation in the Orog Nuur Basin (Southern Mongolia) Using Sentinel-1 SAR Time Series and Ground-Based Photogrammetry

Ullmann

Stauch

2020

Remote Sensing

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This study demonstrates an application-oriented approach to estimate areawide surface roughness from Sentinel1 time series in the semi-arid environment of the Orog Nuur Basin (southern Mongolia) to support recent geomorphological mapping efforts. The relation of selected mono- and multi-temporal SAR features and roughness is investigated by using an empirical multi-model approach and selected 1D and 2D surface roughness indices. These indices were obtained from 48 high-resolution groundbased photogrammetric digital elevation models, which were acquired during a single field campaign. The analysis is backed by a time series analysis, comparing Sentinel-1 features to temporalcorresponding observations and reanalysis datasets on soil moisture conditions, land surface temperature, occurrence of precipitation events, and presence and development of vegetation. Results show that Sentinel1 features are hardly sensitive to the changing surface conditions over none to sparsely vegetated land, indicating very dry conditions throughout the year. Consequently, surface roughness is the dominating factor altering SAR intensity. The best correlation is found for the combined surface roughness index ZValue (ratio between the root mean square height and the correlation length) and the mean summer VH intensity with an r2 coefficient of 0.83 and an RootMeanSquare Error of 0.032.

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“…Usualmente, el método SPM también es usado el límite de su rango de validez, s ∼ 0,05λ , produciendo resultados satisfactorios [9,10,13,14]. En el caso de suelo desnudo y para el rango de microondas en banda L (λ = 25 cm), la condición de validez se cumple si la altura rms de la superficie cumple s < 1,25 cm, lo que es una hipótesis razonable para suelos de agricultura sin vegetación, en donde s ∼ 1 cm [5,6,15].…”

Section: Cálculo Del Patrón De Interferenciaunclassified

“…En el marco de este esquema, cuando un satélite de la red GPS ilumina una superficie, se genera una señal dispersada que depende, principalmente, de dos aspectos: i) la geometría de la superficie; ii) las características dieléctricas de la misma. Teniendo en cuenta que siempre se trabaja con superficies reales, los perfiles de las mismas no se describen a través de funciones analíticas sino mediante parámetros estadísticos [5]. Cuando se monitorea superficies sin vegetación (suelos desnudos) las características geométricas se definen a través de la altura rms de la superficie (s) y de la función de autocorrelación entre dos puntos de la misma (ρ(x, x )); comúnmente, esta función es una Gaussiana con media cero y una longitud típica, que es la longitud de correlación (l).…”

Section: Introductionunclassified

Soil Dielectric Constant Estimation Using GNSS Reflectometry Andthe Interference Pattern Technique

Gomes¹,

Arellana²,

Franco³

et al. 2020

AnAFA

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In this work we present an innovative and low-cost way to estimate the dielectric constant of real soils -which is relatedto soil moisture- using GPS satellite signal. The trajectory of the satellites was followed with an automated device, andwith an antenna type patch was measured the interference pattern generated by the direct GPS signal and that reflectedby the ground. To analyze the acquired signal, an electromagnetic dispersion model based on the method of smallperturbation was used, which may include stratifications in the underground and from which the dielectric constant thatbest fits the measurements was obtained. These values were compared with the obteined using a sensor that measures thesoil dielectric constant textit in-situ. The comparisons shows that the method based on the interference pattern providessatisfactory results to estimate the dielectric constant of real bare soils. Finally, proposals are outlined to improve theresults obtained in this work.

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Effects of Spatial Sampling Interval on Roughness Parameters and Microwave Backscatter over Agricultural Soil Surfaces

Cited by 14 publications

References 27 publications

Influence of Surface Roughness Measurement Scale on Radar Backscattering in Different Agricultural Soils

Influence of Surface Roughness Measurement Scale on Radar Backscattering in Different Agricultural Soils

Surface Roughness Estimation in the Orog Nuur Basin (Southern Mongolia) Using Sentinel-1 SAR Time Series and Ground-Based Photogrammetry

Soil Dielectric Constant Estimation Using GNSS Reflectometry Andthe Interference Pattern Technique

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