Your search keyword '"Font, Jordi"' showing total 8 results

1. Impact of the Local Oscillator Calibration Rate on the SMOS Measurements and Retrieved Salinities.

Author

Gabarro, Carolina, Gonzalez-Gambau, Veronica, Corbella, Ignasi, Torres, Francesc, Martinez, Justino, Portabella, Marcos, and Font, Jordi

Subjects

SOIL moisture measurement, MEASUREMENT of salinity, SEAWATER salinity, DIGITAL signal processing, BRIGHTNESS temperature, MICROWAVE imaging equipment

Abstract

The local oscillators (LOs) of the Soil Moisture and Ocean Salinity mission payload are used to shift the operating frequency of the 72 receivers to an optimal intermediate frequency needed for the signal processing. The LO temperature variations produce phase errors in the visibility, which result in a blurring of the reconstructed brightness temperature (Tb) image. At the end of the commissioning phase, it was decided to calibrate the LO every 10 min while waiting for a more in-depth analysis. During short periods of time, the LO calibration has been performed every 2 min to assess the impact of a higher calibration rate on the quality of the data. In this paper, by means of a decimation experiment, the relative errors of 6- and 10-min calibration interval data sets are estimated using the 2 min as a reference. A noticeable systematic across- and along-track pattern of amplitude \pm0.3 K is observed for Tb differences between 10 and 2 min, whereas this is reduced between 6 and 2 min. A simulation experiment confirms that the nature of such systematic pattern is due to the visibility phase errors induced by the LO calibration rate. Such pattern is propagated into the sea surface salinity (SSS) retrievals. Overall, the SSS error increase (relative to the 2 min SSS data) is about 0.39 and 0.14 psu for the 10- and 6-min data sets, respectively. This paper shows that a LO calibration rate of at least 6 min would noticeably improve the SSS retrievals. [ABSTRACT FROM AUTHOR]

Published

2013

2. Determination of the Sea Surface Salinity Error Budget in the Soil Moisture and Ocean Salinity Mission.

Author

Sabia, Roberto, Camps, Adriano, Talone, Marco, Vall-llossera, Mercè, and Font, Jordi

Subjects

SOIL moisture, SALINITY, CONDENSATION (Meteorology), OCEAN, CONFIGURATION space

Abstract

The Soil Moisture and Ocean Salinity mission will provide sea surface salinity maps over the oceans, beginning in late 2009. In this paper an ocean salinity error budget is described, an analysis needed to identify the magnitude of the error sources associated with the retrieval. Instrumental, external noise sources, and geophysical errors have been analyzed, stressing their relative impact. This paper includes results from previous studies, addressing the impact of multisource auxiliary sea surface temperature and wind speed data on the final salinity error. It provides, moreover, a sensitivity analysis to the uncertainty of the auxiliary salinity field. Salinity retrieval has been addressed in a wide set of configurations of the inversion algorithm. [ABSTRACT FROM AUTHOR]

Published

2010

3. Simulated SMOS Levels 2 and 3 Products: The Effect of Introducing ARGO Data in the Processing Chain and Its Impact on the Error Induced by the Vicinity of the Coast.

Author

Talone, Marco, Camps, Adriano, Mourre, Baptiste, Sabia, Roberto, Vall-llossera, Mercè, Gourrion, Jérôme, Gabarró, Carolina, and Font, Jordi

Subjects

SOIL moisture, SALINITY, MICROWAVE imaging, RADIOMETERS, COASTS

Abstract

The Soil Moisture and Ocean Salinity (SMOS) Mission is the second of the European Space Agency's Living Planet Program Earth Explorer Opportunity Missions, and it is scheduled for launch in July 2009. Its objective is to provide global and frequent soil-moisture and sea-surface-salinity (SSS) maps, SMOS' single payload is the Microwave Imaging Radiometer by Aperture Synthesis (MIRAS) sensor, an L-band 2-D aperture-synthesis interferometric radiometer. For the SSS, the output products of SMOS, at Level 3, will have global coverage and an accuracy of 0.1-0.4 psu (practical salinity units) over 100 x 100-200 x 200 km² in 10-30 days. During the last few years, several studies have pointed out the necessity of combining auxiliary data with the MIRAS-measured brightness temperature to provide the required accuracy. In this paper, we propose and test two techniques to include auxiliary data in the SMOS SSS retrieval algorithm. Aiming at this, pseudo-SMOS Level-3 products have been generated according to the following steps: 1) A North Atlantic configuration of the NEMO-OPA ocean model has been run to provide consistent geophysical parameters; 2) the SMOS end-to-end processor simulator has been used to compute the brightness temperatures as measured by the MIRAS; 3) the SMOS Level-2 processor simulator has been applied to retrieve SSS values for each point and overpass; and 4) Level-2 data have been temporally and spatially averaged to synthesize Level-3 products. In order to assess the impact of the proximity to the coast at Level 3, and the effect of these techniques on it, two different zones have been simulated: the first one in open ocean and the second one in a coastal region, near the Canary Islands (Spain) where SMOS and Aquarius CAL/VAL activities are foreseen. Performance exhibits a clear improvement at Level 2 using the techniques proposed; at Level 3, a smaller effect has been recorded. Coastal proximity has been found to affect the retrieval of up to 150 and 300 km from the coast, at Levels 2 and 3, respectively. Results for both scenarios are presented and discussed. [ABSTRACT FROM AUTHOR]

Published

2009

4. Overview of the SMOS Sea Surface Salinity Prototype Processor.

Author

Zine, Sonia, Boutin, Jacqueline, Font, Jordi, Reul, Nicolas, Waldteufel, Philippe, Gabanó, Carolina, Tenerelli, Joseph, Petitcolin, Francois, Vergely, Jean-Luc, Talone, Marco, and Deiwart, Steven

Subjects

INTERFEROMETERS, OPTICAL instruments, REMOTE sensing, ARTIFICIAL satellites, MICROWAVE remote sensing, SOIL moisture measurement, OCEANOGRAPHY, SALINITY

Abstract

The L-band interferometric radiometer onboard the Soil Moisture and Ocean Salinity mission will measure polarized brightness temperatures (Tb). The measurements are affected by strong radiometric noise. However, during a satellite overpass, numerous measurements are acquired at various incidence angles at the same location on the Earth's surface. The sea surface salinity (SSS) retrieval algorithm implemented in the Level 2 Salinity Prototype Processor (L2SPP) is based on an iterative inversion method that minimizes the differences between Tb measured at different incidence angles and Tb simulated by a full forward model. The iterative method is initialized with a first-guess surface salinity that is iteratively modified until an optimal fit between the forward model and the measurements is obtained. The forward model takes into account atmospheric emission and absorption, ionospheric effects (Faraday rotation), scattering of celestial radiation by the rough ocean surface, and rough sea surface emission as approximated by one of three models. Potential degradation of the retrieval results is indicated through a flagging strategy. We present results of tests of the L2SPP involving horizontally uniform scenes with no disturbing factors (such as sun glint or land proximity) other than wind-induced surface roughness. Regardless of the roughness model used, the error on the retrieved SSS depends on the location within the swath and ranges from 0.5 psu at the center of the swath to 1.7 psu at the edge, at 35 psu and 15 °C. Dual-polarization (DP) mode provides a better correction for wind-speed (WS) biases than pseudofirst Stokes mode (ST1). For a WS bias of -1 m . s-1, the corresponding SSS bias at the center of the swath is equal to -0.3 psu in DP mode and to -0.5 psu in ST1 mode. The inversion methodology implicitly assumes that WS errors follow a Gaussian distribution, even though these errors should follow more closely a Rayleigh distribution. [ABSTRACT FROM AUTHOR]

Published

2008

5. The Determination of Surface Salinity With the European SMOS Space Mission.

Author

Font, Jordi, Lagerloef, Gary S. E., Vine, David M. Le, Camps, Adriano, and Zanifé, Ouan-Zan

Subjects

*SOIL salinity, *SOIL moisture, *TEMPERATURE, *SALINITY, *RADIOMETERS, *FIELD research

Abstract

The European Space Agency Soil Moisture and Ocean Salinity (SMOS) mission aims at obtaining global maps of soil moisture and sea surface salinity from space for large-scale and climatic studies. It uses an L-band (1400-1427 MHz) Microwave Interferometric Radiometer by Aperture Synthesis to measure brightness temperature of the earth's surface at horizontal and vertical polarizations (Th and Tv). These two parameters will be used together to retrieve the geophysical parameters. The retrieval of salinity is a complex process that requires the knowledge of other environmental information and an accurate processing of the radiometer measurements. Here, we present recent results obtained from several studies and field experiments that were part of the SMOS mission, and highlight the issues still to be solved. [ABSTRACT FROM AUTHOR]

Published

2004

6. Wind Speed Effect on L-Band Brightness Temperature Inferred From EuroSTARRS and WISE 2001 Field Experiments.

Author

Etcheto, Jacqueline, Dinnat, Emmanuel P., Boutin, Jacqueline, Camps, Adriano, Miller, J., Contardo, Stephanie, Wesson, J., Font, Jordi, and Long, David G.

Subjects

WIND speed, BRIGHTNESS temperature, FIELD research, RADIOMETERS, EMISSIVITY

Abstract

The results from two field experiments in the Mediterranean Sea are used to study the wind speed dependence of brightness temperature at L-band. During the EuroSTARRS airborne experiment, an L-band radiometer made measurements across a large wind speed gradient, enabling us to study this dependence at high wind speed. We compare our results with a two-scale emissivity model using several representations of the sea state spectrum. While the results are encouraging, unfortunately the accuracy of the measurements does not permit us to distinguish between the so-called twice Durden and Vesecky spectrum and the Elfouhaily spectrum above 7 m . s-1 The effect of foam is certainly small. During the WISE 2001 field experiment carried on an oil rig, we studied this dependence at low wind speed, finding an abrupt decrease of the wind speed effect on the brightness temperature below 3m . s-1. [ABSTRACT FROM AUTHOR]

Published

2004

7. Soil Moisture Retrieval from Space: The Soil Moisture and Ocean Salinity (SMOS) Mission.

Author

Kerr, Yann H., Waldteufel, Philippe, Wigneron, Jean-Pierre, Martinuzzi, Jean-Michel, Font, Jordi, and Berger, Michael

Subjects

SOIL moisture, SALINITY

Abstract

Presents information on a study which described the antenna synthesis methods for Soil Moisture and Ocean Salinity mission. Mission description; Data acquisition and processing; Calibration and validation; Conclusion.

Published

2001

8. Introduction to the Special Issue on the ESA's Soil Moisture and Ocean Salinity Mission (SMOS)—Instrument Performance and First Results.

Author

Kerr, Yann H., Font, Jordi, Martin-Neira, Manuel, and Mecklenburg, Susanne

Subjects

*SOIL moisture measurement, *MEASUREMENT of salinity, *SEAWATER salinity, *REMOTE sensing, *ARTIFICIAL satellites

Abstract

The introductory overview and 27 papers in this special issue present information on instrument performance and first results of the SMOS mission. [ABSTRACT FROM AUTHOR]

Published

2012