Mapping saturated areas with a helicopter‐borne C band scatterometer

Brun, Carlos; Bernard, R.; Vidal-Madjar, D.; Gascuel‐Odoux, Chantal; Mérot, Philippe; Duchesne, Jean; Nicolas, H.

doi:10.1029/wr026i005p00945

Cited by 14 publications

(8 citation statements)

References 24 publications

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“…Surface runoff occurs when rainfall intensity exceeds the soil infiltration capacity or when rainfall volumes exceed the soil storage capacity (Zobeck and Onstad, 1987;Boiffin et al, 1988;Brun et al, 1990;Le Bissonnais, 1990). For both of these variables, in addition to vegetation and pedological characteristics, soil roughness and moisture content play a major role.…”

Section: Soil Surface Characteristics and Overland Flow And Soil Erosmentioning

confidence: 98%

Operational performance of current synthetic aperture radar sensors in mapping soil surface characteristics in agricultural environments: application to hydrological and erosion modelling

Baghdadi

Cerdan

Zribi

et al. 2007

Hydrological Processes

135

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Abstract:Synthetic aperture radar (SAR) sensors are often used to characterize the surface of bare soils in agricultural environments. They enable the soil moisture and roughness to be estimated with constraints linked to the configurations of the sensors (polarization, incidence angle and radar wavelength). These key soil characteristics are necessary for different applications, such as hydrology and risk prediction.This article reviews the potential of currently operational SAR sensors and those planned for the near future to characterize soil surface as a function of users' needs. It details what it is possible to achieve in terms of mapping soil moisture and roughness by specifying optimal radar configurations and the precision associated with the estimation of soil surface characteristics.The summary carried out for the present article shows that mapping soil moisture is optimal with SAR sensors at low incidence angles (<35°). This configuration, which enables an estimated moisture accuracy greater than 6% is possible several times a month taking into account all the current and future sensors. Concerning soil roughness, it is best mapped using three classes (smooth, moderately rough, and rough). Such mapping requires high-incidence data, which is possible with certain current sensors (RADARSAT-1 and ASAR both in band C). When L-band sensors (ALOS) become available, this mapping accuracy should improve because the sensitivity of the radar signal to Soil Surface Characteristics (SSC) increases with wavelength. Finally, the polarimetric mode of certain imminent sensors (ALOS, RADARSAT-2, TerraSAR-X, etc.), and the possibility of acquiring data at very high spatial resolution (metre scale), offer great potential in terms of improving the quality of SSC mapping.

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Section: Soil Surface Characteristics and Overland Flow And Soil Erosmentioning

confidence: 98%

Operational performance of current synthetic aperture radar sensors in mapping soil surface characteristics in agricultural environments: application to hydrological and erosion modelling

Baghdadi

Cerdan

Zribi

et al. 2007

Hydrological Processes

135

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“…A remote sensing technique to map saturated areas would be extremely useful, even if repeat times were long or irregular, but most remote sensing methods are limited by insensitivity of emmissivities close to saturation and by image speckle from wet surfaces (e.g. Brun et al, 1990). On the other hand, a perceptual model for the response of this catchment includes the fact that the catchment is very wet for much of the year and that the dynamics of the contributing areas are important for runoff formation.…”

Section: Mapping Saturated Areasmentioning

confidence: 99%

On constraining TOPMODEL hydrograph simulations using partial saturated area information

Blažková

Beven

Kulasova

2002

Hydrological Processes

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Abstract:This study uses field observations of the extent of saturated area over limited areas of the small Uhlirska catchment (1Ð87 km 2 ) in the Czech Republic in calibrating the parameters of a version of TOPMODEL. The field information is used within the GLUE methodology, which involves evaluating many different randomly chosen parameter sets within the chosen model structure. The different parameter sets are evaluated on performance in both discharge prediction and prediction of the observed saturated areas using appropriate likelihood measures. The results show that the saturated area information results in a strong constraint of the transmissivity parameter of the model, but that the other parameters show good fits across most of the range over which they are sampled. Quite different posterior distributions for the transmissivity parameter are found for the two different years of data used in conditioning the model. The effect on the prediction bounds for stream discharges is much less, perhaps because the transmissivity parameter combines with different values of the other parameters in the two years to capture the dominant modes of discharge response of the catchment.

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“…RESULTS AND DISCUSSION The threshold detection scheme Figure 5 presents the saturated areas predictions for the ground truth zone when a threshold of À7 dB (Brun et al, 1990) is applied to the ®ltered images for Julian days 37, 46 and 82. The major rainfall event of this dry winter occurred between these ®rst two dates, followed by about one month with practically no rain, at the end of which the third image was taken ( Figure 6).…”

Section: Filtering Multitemporal Sar Imagesmentioning

confidence: 99%

“…Based on a helicopter-borne C-band scatterometer and extensive ground experiments over the CoeÈ t-Dan catchment in French Brittany, Brun et al (1990) have proposed mapping of the saturated area extent by applying a threshold on the back-scattering coecient. For the ERS synthetic aperture radar (SAR) con®guration, a threshold value of À7 dB was found independent of the nature of the ®eld surface.…”

Section: Introductionmentioning

confidence: 99%

Radar remote sensing of the source areas from the Coët-Dan catchment

Gineste¹,

Puech²,

Mérot

1998

Hydrol. Process.

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Abstract:As interest shifts to the development of models for predicting runo quality, identi®cation of the source areas for runo becomes increasingly important. Active microwave remote sensing has a unique potential for surveying source areas at the catchment scale. Thresholding of the back-scattering coecient was initially proposed but proved unsatisfactory when applied to the ERS-1 SAR multitemporal images acquired during winter 1992 over the CoeÈ t-Dan catchment, concomitantly with ground observations. Dierence images may, instead, allow the wettest part of the catchment to be identi®ed provided that the two images encompass a marked hydrological event. A saturation plot could not however be obtained for each date; the use of a pair of images may be further limited by the residual speckle (although carefully ®ltered using the multitemporal information) and a slight inaccuracy in the SAR image calibration. It is therefore argued that considering the whole temporal back-scatter pro®le would be, at present, a safer approach to the remote sensing of saturated areas. The back-scatter temporal standard deviation appears, in this light, as a possible good indicator of the local saturation likelihood during the period of study: it is based on the fact that saturation develops on parts of the catchment that are wetter than the others through lateral recharge. Possible applications within the TOPMODEL framework are discussed. #

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Mapping saturated areas with a helicopter‐borne C band scatterometer

Cited by 14 publications

References 24 publications

Operational performance of current synthetic aperture radar sensors in mapping soil surface characteristics in agricultural environments: application to hydrological and erosion modelling

Operational performance of current synthetic aperture radar sensors in mapping soil surface characteristics in agricultural environments: application to hydrological and erosion modelling

On constraining TOPMODEL hydrograph simulations using partial saturated area information

Radar remote sensing of the source areas from the Coët-Dan catchment

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