| Autor: |
Hakkarinen, I., Adler, R. |
| Zdroj: |
Meteorology & Atmospheric Physics; Sep1988, Vol. 38 Issue 3, p164-182, 19p |
| Abstrakt: |
High spatial resolution data from an airborne microwave imaging radiometer operating at 92 and 183 GHz (0.32 and 0.16 cm wavelengths) are compared with ground-based radar data for a series of observations of precipitating convective systems. An inverse relationship between microwave brightness temperature ( T) and radar-derived rain rate ( RR) is observed. Differences in the empirical curves between midlatitude and tropical cloud systems are related to the differing microphysical and dynamical environments. Cold T features in the aircraft images are collocated with high reflectivity values in the radar data. Over a water back-ground, which has a low surface emissivity at these frequencies, small convection produces an increase in T at 92 GHz due to emission by liquid water in the cloud. As the convection deepens and ice forms, T at both frequencies decreases rapidly with increasing rain rate. The large decrease in T with increasing storm intensity is due to scattering of upwelling radiation by precipitation-sized ice particles within the clouds. With high rain rates, there is little difference between T observed over both land and water backgrounds. The T features in the aircraft imagery are qualitatively similar to radar echoes in plan position indicator (PPI) images. Areas of extremely cold T (<150 K) coincide with high radar reflectivities. The highest correlations between microwave and radar features with regard to location, intensity, and shape occur more frequently with mid-to upperlevel echoes rather than low-level reflectivity features. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
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