Modeling the beamfilling correction for microwave retrieval of oceanic rainfall /

retrieval bias caused by the combined effects of non-uniform

Bibliographic Details
Main Author: Wang, Shaohua Alex, 1961-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1996.
Subjects:
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Description
Summary:retrieval bias caused by the combined effects of non-uniform
distribution of rainfall intensity within the field of view
(FOV) of a microwave radiometer and the non-linear
relationship between rain rate and microwave brightness
temperature over an oceanic backgound. 'The beamfilling
problem has been studied by many investigators. It is found
that even though the beamfilling error for each FOV does
vary, the ensemble mean beamfluing error is rather stable
and, therefore, can be corrected by a multiplicative constant
that depends on the spatial resolution of the observation.
This constant is referred to as Beamfilling Correction Factor
(BCF).
In previous studies, the beamfluing correction was
derived using two-dimensional rainfall intensity fields
estimated from radar observations as the basis for
simulation studies. Vertical structure and the structure
along a sloping radiometer view path have been ignored to
date. However, because a radiometer measures the total
opacity along its beam as reflected from the ocean
surface, and because the absorption coefficient is
approximately linear in the rain rate, averaging along
the beam does not introduce appreciable error. From the
random field theorem, it is known that the variance of a
local average is smaller than that of the underlying
point process. A reduction in variance will certainly
reduce the beamfifling error, suggesting that previous
studies have overestimated the beamfilling correction. A
simulation study based on radar observed rainfall data is
conducted to estimate the difference between the
beamfdling error derived from three-dimensional radar data
and that derived from two-dimensional radar data. The
three dimensional radar rainfall data used here were
collected by the Airborne Rain MApping Radar (ARMAR)
during the TOGACOARE experiment. The ARMAR data have a
spatial resolution of less than half of a kilometer which
is much better than the 4 km resolution of the radar data
collected during GATE. Range sidelobe contamination and
signal attenuation through rain associated with ARMAR data
are properly treated. A number of simulations were
conducted with different FOV's and for different heights
of the O'C isotherm (freezing level). The results showed
that the beamfi-Iling error is significantly reduced when
the three-dimensional rainfall field is used relative to
the results when the two-dimensional rainfall field is
used for the simulation. Additionally, the results showed
that the BCF is logarithmically related to FOV size and
linearly related to the freezing level. Finally, a
beamfilling correction factor formula that can be used to
estimate the BCF for given radiometer parameters (e.g..
frequency, polarization, viewing angle, spatial
resolution) and freezing level was also derived from these
simulation experiments.
Item Description:Vita.
"Major Subject: Meteorology".
Physical Description:xii, 100 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references.