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The spatial-scale dependence of the observed anisotropy of reflected and emitted radiation

ScholarsArchive at Oregon State University

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Title The spatial-scale dependence of the observed anisotropy of reflected and emitted radiation
Names Ye, Qian (creator)
Coakley, James A. Jr (advisor)
Date Issued 1993-08-20 (iso8601)
Note Graduation date: 1994
Abstract The Earth Radiation Budget Experiment (ERBE) uses Angular Dependence Models
(ADMs) to convert satellite observed radiances to radiative fluxes at the top of the
atmosphere. Owing to errors in scene identification and to the relationship between
the spatial scales of cloud systems and the spatial resolution of the ERBE scanner, the
anisotropy of the radiation fields determined from ERBE observations was suspected
of exhibiting a field of view size dependence. In order to remove effects due to the
spatial scale of cloud fields, ERBE scanner observations from the Earth Radiation Budget
Satellite (ERBS) were averaged to construct observations having a constant size field of
view for all scan angles. Comparing the anisotropy for constant size fields of view with
that obtained using unaltered full-resolution scanner observations, it was found that there
were significant and systematic differences of the order of 5-10% for all scene types.
The frequencies of occurrence for clear, partly cloudy, mostly cloudy and overcast
cloud categories identified by the ERBE scene identification algorithm were calculated
for the constant size field of view observations. It was found that the ERBE scene
identification method failed to correctly identify scene types. A bispectral threshold
method was developed for scene identification. In the determination of the thresholds,
the ERBE scene identification method was assumed to be correct for nadir observations.
The thresholds were then determined so that the population of scene types remained
constant from nadir to limb for the constant size field of view observations. ADMs
were developed using the threshold scene identification method. Results showed that the
spatial-scale dependence of the ADMs was significantly reduced. The threshold ADMs
satisfied the principle of reciprocity more closely than did the ERBE ADMs for all cloud
categories. Using the threshold scene identification, the view zenith angle dependence
of the global average albedo and the longwave flux were significantly reduced compared
with those obtained using the ERBE scene identification. The estimated global average
albedo increases from 0.282 for the ERBE algorithm to 0.299 for the threshold algorithm.
There was no significant change for the value of the estimated longwave flux.
Genre Thesis/Dissertation
Topic Solar radiation -- Mathematical models
Identifier http://hdl.handle.net/1957/28890

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