Validation of a Large-Scale Simulated Brightness Temperature Dataset Using SEVIRI Satellite Observations

In this study, the accuracy of a simulated infrared brightness temperature dataset derived from a unique large-scale, high-resolutionWeather Research and Forecasting (WRF) Model simulation is evaluated through a comparison with Spinning Enhanced Visible and Infrared Imager (SEVIRI) observations. Ove...

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Bibliographic Details
Published in:Journal of applied meteorology and climatology 2009-08, Vol.48 (8), p.1613-1626
Main Authors: Otkin, Jason A., Greenwald, Thomas J., Sieglaff, Justin, Huang, Hung-Lung
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Atmosphere
Brightness
Brightness temperature
Cirrus clouds
Clear sky
Cloud cover
Cloud types
Clouds
Convection
Convection clouds
Datasets
Earth, ocean, space
Endangered & extinct species
Error analysis
Exact sciences and technology
External geophysics
Gas absorption
Ice clouds
Infrared analysis
Inspection
Meteorological satellites
Meteorology
Microphysics
Modeling
Modelling
Pixels
Probability theory
Proxy reporting
Satellite observation
Sensors
Simulation
Simulations
Surface radiation temperature
Temperate regions
Temperature
Temperature differences
Temperature gradients
Tropical convection
Water vapor
Weather forecasting
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Summary:In this study, the accuracy of a simulated infrared brightness temperature dataset derived from a unique large-scale, high-resolutionWeather Research and Forecasting (WRF) Model simulation is evaluated through a comparison with Spinning Enhanced Visible and Infrared Imager (SEVIRI) observations. Overall, the analysis revealed that the simulated brightness temperatures realistically depictmany of the observed features, although several large discrepancies were also identified. The similar shapes of the simulated and observed probability distributions calculated for each infrared band indicate that the model simulation realistically depicted the cloud morphology and relative proportion of clear and cloudy pixels. A traditional error analysis showed that the largest model errors occurred over central Africa because of a general mismatch in the locations of deep tropical convection and intervening regions of clear skies and low-level cloud cover. A detailed inspection of instantaneous brightness temperature difference (BTD) imagery showed that the modeling system realistically depicted the radiative properties associated with various cloud types. For instance, thin cirrus clouds along the edges of deep tropical convection and within midlatitude cloud shields were characterized by much larger 10.8 – 12.0-μm BTD than optically thicker clouds. Simulated ice clouds were effectively discriminated from liquid clouds and clear pixels by the close relationship between positive 8.7 – 10.8-μm BTD and the coldest 10.8-μm brightness temperatures. Comparison of the simulated and observed BTD probability distributions revealed that the liquid and mixed-phase cloud-top properties were consistent with the observations, whereas the narrower BTD distributions for the colder 10.8-μm brightness temperatures indicated that the microphysics scheme was unable to simulate the full dynamic range of ice clouds.
ISSN:1558-8424
1558-8432
DOI:10.1175/2009jamc2142.1