Abstract
Water resources on Earth become one of the main concerns for society. Therefore, remote sensing methods are still under development in order to improve the picture of the global water cycle. In this context, the microwave bands are the most suitable to study land–water resources. The Soil Moisture and Ocean Salinity (SMOS), satellite mission of the European Space Agency (ESA), is dedicated for studies of the water in soil over land and salinity of oceans. The part of calibration/validation activities in order to improve soil moisture retrieval algorithms over land is done with ground-based passive radiometers. The European Space Agency L-band Microwave Radiometer (ELBARA III) located near the Bubnów wetland in Poland is capable of mapping microwave emissivity at the local scale, due to the azimuthal and vertical movement of the horn antenna. In this paper, we present results of the spatio-temporal mapping of the brightness temperatures on the heterogeneous area of the Bubnów test-site consisting of an area with variable organic matter (OM) content and different type of vegetation. The soil moisture (SM) was retrieved with the L-band microwave emission of the biosphere (L-MEB) model with simplified roughness parametrization (SRP) coupling roughness and optical depth parameters. Estimated soil moisture values were compared with in-situ data from the automatic agrometeorological station. The results show that on the areas with a relatively low OM content (4–6%—cultivated field) there was good agreement between measured and estimated SM values. Further increase in OM content, starting from approximately 6% (meadow wetland), caused an increase in bias, root mean square error (RMSE), and unbiased RMSE (ubRMSE) values and a general drop in correlation coefficient (R). Despite a span of obtained R values, we found that time-averaged estimated SM using the L-MEB SRP approach strongly correlated with OM contents.
Highlights
Water is one of the most critical resources on Earth
The European Space Agency (ESA) L-band azimuth tracker for automatic mapping of the microwave characteristics of this heterogeneous area microwave radiometer (ELBARA) on the Bubnów test site is equipped with an azimuth tracker for while other ESA L-band microwave radiometer (ELBARA) tower radiometers have fixed azimuth direction
Spatial distributions of soil granulometric fractions and organic matter contents are shown in Figure 2
Summary
Water is one of the most critical resources on Earth. It forms the global climate and supports the life evaluation on Earth as well as determines the ability for food production as a component in the photosynthesis process. The ESA L-band azimuth tracker for automatic mapping of the microwave characteristics of this heterogeneous area microwave radiometer (ELBARA) on the Bubnów test site is equipped with an azimuth tracker for while other ELBARA tower radiometers have fixed azimuth direction It allows studying the SM automatic mapping of the microwave characteristics of this heterogeneous area while other ELBARA retrieval models in the presence of the naturally variable amount of organic matter content in soil tower radiometers have fixed azimuth direction. It allows studying the SM retrieval models in the unavailable on the other test sites. Values were compared with data recorded by the agrometeorological station and evaluated statistically
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