Your search keyword '"Doubkova, Marcela"' showing total 10 results

1. How do Spatial Scale, Noise, and Reference Data affect Empirical Estimates of Error in ASAR Derived 1 km Resolution Soil Moisture?

Author

Doubkova, Marcela, Dostalova, Alena, Van Dijk, Albert, Bloschl, Gunter, Wagner, Wolfgang, Fernandez Prieto, D., Doubkova, Marcela, Dostalova, Alena, Van Dijk, Albert, Bloschl, Gunter, Wagner, Wolfgang, and Fernandez Prieto, D.

Abstract

The performance of the advanced synthetic aperture radar (ASAR) global mode (GM) surface soil moisture (SSM) data was studied over Australia by means of two widely used bivariate measures, the root-mean-square error (RMSE) and the Pearson correlation coefficient (R). By computing RMSE and R at multiple spatial scales and for different data combinations, we assessed how, and at which scales, the spatial sampling error, noise, and the choice of the reference data impact on RMSE and R. The results reveal large changes in RMSE and R with continental average values of 8% and 18% for the RMSE of relative soil moisture saturation and between 0.4 and 0.7 for R depending on the spatial scale of aggregation and the choice of reference data. The combined effect of noise and spatial sampling error accounted for a 79% RMSE increase at 1 km and predominated over the error due to the choise of the reference data also at 5 km scale. The effect of noise on RMSE strongly diminished at spatial scales ≥ km. By contrast, the impact of uncertainties in the reference data was larger on than on RMSE. This highlights the better potential of to estimate the benefit of observations prior to data assimilation. Based on our results, it is further suggested that a potential way for an improved ASAR GM SSM error assessment is to: 1) aggregate the data to ≥ km resolution to minimize the noise; 2) subtract the spatial sampling error within the coarse resolution footprint; and 3) remove the reference uncertainty using advanced techniques such as triple collocation.

Published

2014

2. Prospects of Sentinel-1 for land applications

Author

Wagner, Wolfgang, primary, Sabel, Daniel, additional, Doubkova, Marcela, additional, Hornacek, Michael, additional, Schlaffer, Stefan, additional, and Bartsch, Annett, additional

Published

2012

3. Evaluation of the ASAR GM soil moisture product

Author

Doubkova, Marcela, primary, Dorigo, Wouter, additional, Hegyiova, Alena, additional, and Wagner, Wolfgang, additional

Published

2012

4. On the ability of the ERS scatterometer to detect vegetation properties

Author

Doubkova, Marcela, primary, Naeimi, Vahid, additional, Wagner, Wolfgang, additional, and Henebry, Geoffrey, additional

Published

2009

5. Scatterometer and ScanSAR soil moisture observations of the contiguous United States

Author

Pathe, Carsten, primary, Wagner, Wolfgang, additional, Sabel, Daniel, additional, Bartalis, Zoltan, additional, Doubkova, Marcela, additional, and Naeimi, Vahid, additional

Published

2009

6. The medium resolution soil moisture dataset: Overview of the SHARE ESA DUE TIGER project

Author

Doubkova, Marcela, primary, Bartsch, Annett, additional, Pathe, Carsten, additional, Sabel, Daniel, additional, and Wagner, Wolfgang, additional

Published

2009

7. Similarities Between Spaceborne Active and Airborne Passive Microwave Observations at 1 km Resolution.

Author

Rudiger, Christoph, Doubkova, Marcela, Larsen, Joshua R., Wagner, Wolfgang, and Walker, Jeffrey P.

Abstract

For the first time, airborne passive microwave data were collected at 1 km resolution over parts of Central Australia coinciding with spaceborne active data, allowing a comparison of such data sets acquired at medium (1 km) spatial resolution. L-band airborne passive microwave scenes were compared with C-band scenes and temporal parameters from the Advanced Synthetic Aperture Radar. It was found that the radar-returned signal, as well as the “sensitivity” and “correlation” parameters derived from the long time-series of the ASAR GM data, is similar to spatial patterns in the passive microwave data, suggesting that similar physical interactions are underlying both data sets, especially across heterogeneous landscapes. Comparable patterns found over the dry Lake Eyre salt bed (r^2=0.37) suggest that very high-resolution C-band radar data may be used to describe subpixel heterogeneity within coarse resolution radiometer data, such as the future Soil Moisture Active Passive mission. [ABSTRACT FROM PUBLISHER]

Published

2014

8. Potential for High Resolution Systematic Global Surface Soil Moisture Retrieval via Change Detection Using Sentinel-1.

Author

Hornacek, Michael, Wagner, Wolfgang, Sabel, Daniel, Truong, Hong-Linh, Snoeij, Paul, Hahmann, Thomas, Diedrich, Erhard, and Doubkova, Marcela

Abstract

The forthcoming two-satellite GMES Sentinel-1 constellation is expected to render systematic surface soil moisture retrieval at 1 km resolution using C-band SAR data possible for the first time from space. Owing to the constellation's foreseen coverage over the Sentinel-1 Land Masses acquisition region—global approximately every six days, nearly daily over Europe and Canada depending on latitude—in the high spatial and radiometric resolution Interferometric Wide Swath (IW) mode, the Sentinel-1 mission shows high potential for global monitoring of surface soil moisture by means of fully automatic retrieval techniques. This paper presents the potential for providing such a service systematically over Land Masses and in near real time using a change detection approach, concluding that such a service is—subject to the mission operating as foreseen—expected to be technically feasible. The work presented in this paper was carried out as a feasibility study within the framework of the ESA-funded GMES Sentinel-1 Soil Moisture Algorithm Development (S1-SMAD) project. [ABSTRACT FROM PUBLISHER]

Published

2012

9. Validation of the ASAR Global Monitoring Mode Soil Moisture Product Using the NAFE'05 Data Set.

Author

Mladenova, Iliana, Lakshmi, Venkat, Walker, Jeffrey P., Panciera, Rocco, Wagner, Wolfgang, and Doubkova, Marcela

Subjects

SOIL moisture, RADAR, RADIOMETERS, SPATIAL analysis (Statistics), STATISTICAL correlation

Abstract

The Advanced Synthetic Aperture Radar (ASAR) Global Monitoring (GM) mode offers an opportunity for global soil moisture (SM) monitoring at much finer spatial resolution than that provided by the currently operational Advanced Microwave Scanning Radiometer for the Earth Observing System and future planned missions such as Soil Moisture and Ocean Salinity and Soil Moisture Active Passive. Considering the difficulties in modeling the complex soil-vegetation scattering mechanisms and the great need of ancillary data for microwave backscatter SM inversion, algorithms based on temporal change are currently the best method to examine SM variability. This paper evaluates the spatial sensitivity of the ASAR GM surface SM product derived using the temporal change detection methodology developed by the Vienna University of Technology. This evaluation is made for an area in southeastern Australia using data from the National Airborne Field Experiment 2005. The spatial evaluation is made using three different types of SM data (station, field, and airborne) across several different scales (1-25 km). Results confirmed the expected better agreement when using point (Rstation = 0.75) data as compared to spatial (RPLMR, 1km = 0.4) data. While the aircraft-ASAR GM correlation values at 1-km resolution were low, they significantly improved when averaged to 5 km (RPLMR, 5km = 0.67) or coarser. Consequently, this assessment shows the ASAR GM potential for monitoring SM when averaged to a spatial resolution of at least 5 km. [ABSTRACT FROM AUTHOR]

Published

2010

10. Using ENVISAT ASAR Global Mode Data for Surface Soil Moisture Retrieval Over Oklahoma, USA.

Author

Pathe, Carsten, Wagner, Wolfgang, Sabel, Daniel, Doubkova, Marcela, and Basara, Jeffrey B.

Subjects

SYNTHETIC aperture radar, IMAGING systems, REMOTE sensing, ARTIFICIAL satellites, SOIL moisture measurement, HYDROLOGY

Abstract

The advanced synthetic aperture radar (ASAR) on-board of the satellite ENVISAT can be operated in global monitoring (GM) mode. ASAR GM mode has delivered the first global multiyear C-band backscatter data set in HH polarization at a spatial resolution of 1 km. This paper investigates if ASAR GM can be used for retrieving soil moisture using a change detection approach over large regions. A method previously developed for the European Remote Sensing (ERS) scatterometer is adapted for use with ASAR GM and tested over Oklahoma, USA. The ASAR-GM-derived relative soil moisture index is compared to 50-km ERS soil moisture data and pointlike in situ measurements from the Oklahoma MESONET. Even though the scale gap from ASAR GM to the in situ measurements is less pronounced than in the case of the ERS scatterometer, the correlation for ASAR against the in situ measurements is, in general, somewhat weaker than for the ERS scatterometer. The analysis suggests that this is mainly due to the much higher noise level of ASAR GM compared to the ERS scatterometer. Therefore, some spatial averaging to 3-10 km is recommended to reduce the noise of the ASAR GM soil moisture images. Nevertheless, the study demonstrates that ASAR GM allows resolving spatial details in the soil moisture patterns not observable in the ERS scatterometer measurements while still retaining the basic capability of the ERS scatterometer to capture temporal trends over large areas. [ABSTRACT FROM AUTHOR]

Published

2009