An Empirical Orthogonal Function Iteration Approach for Obtaining Homogeneous Radiative Fluxes from Satellite Observations

An Empirical Orthogonal Function Iteration Approach for Obtaining Homogeneous Radiative Fluxes from Satellite Observations

Conventional observations of climate parameters are sparse in space and/or time, and the representativeness of such information needs to be optimized. Observations from satellites provide improved spatial coverage over point observations; however, they pose new challenges for obtaining homogeneous c...

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Bibliographic Details
Published in:Journal of applied meteorology and climatology Vol. 46; no. 4; pp. 435 - 444
Main Authors: Zhang, Banglin, Pinker, Rachel T., Stackhouse, Paul W.
Format: Journal Article
Language:English
Published: Boston, MA American Meteorological Society 01-04-2007
Subjects:
Atmosphere
Atmospheric models
Atmospherics
Climatology
Clouds
Covariance
Data collection
Earth
Earth, ocean, space
Exact sciences and technology
External geophysics
Geophysics. Techniques, methods, instrumentation and models
Hydrologic cycle
Interpolation
Meteorological satellites
Meteorology
Observational research
Other topics in atmospheric geophysics
Principal components analysis
Research centers
Satellites
Spatial resolution
Water cycle
Climatic data
Space remote sensing
Radiation flux
Iterative process
Time series
Empirical orthogonal function
Satellite observation
Geostationary satellite
Polar orbiting satellite
homogeneity
homogenization
interpolation
Observation data
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Summary:Conventional observations of climate parameters are sparse in space and/or time, and the representativeness of such information needs to be optimized. Observations from satellites provide improved spatial coverage over point observations; however, they pose new challenges for obtaining homogeneous coverage. Surface radiative fluxes, the forcing functions of the hydrologic cycle and biogeophysical processes, are now becoming available from global-scale satellite observations. They are derived from independent satellite platforms and sensors that differ in temporal and spatial resolution and in the size of the footprint from which information is derived. Data gaps, degraded spatial resolution near boundaries of geostationary satellites, and different viewing geometries in areas of satellite overlap could result in biased estimates of radiative fluxes. In this study will be discussed issues related to the sources of inhomogeneity in surface radiative fluxes as derived from satellites, development of an approach to obtain homogeneous datasets, and application of the method to the widely used International Satellite Cloud Climatology Project data that currently serve as a source of information for deriving estimates of surface and top-of-the-atmosphere radiative fluxes. Introduced is an empirical orthogonal function (EOF) iteration scheme for homogenizing the fluxes. The scheme is evaluated in several ways, including comparison of the inferred radiative fluxes with ground observations, both before and after the EOF approach is applied. On the average, the latter reduces the RMS error by about 2–3 W m−2.
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ISSN:1558-8424
1558-8432
DOI:10.1175/JAM2478.1