Improved all-weather atmospheric sounding using hyperspectral microwave observations

We introduce a new hyperspectral microwave remote sensing modality for atmospheric sounding, driven by recent advances in microwave device technology that now permit receiver arrays that can multiplex multiple broad frequency bands into more than ~ 100 spectral channels, thus improving both the vert...

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Bibliographic Details
Main Authors: Blackwell, W J, Leslie, R V, Pieper, M L, Samra, J E
Format: Conference Proceeding
Language:English
Subjects:
Atmospheric measurements
Atmospheric modeling
hyperspectral
Hyperspectral sensors
Microwave
Microwave measurements
Microwave radiometry
Microwave theory and techniques
Ocean temperature
radiometry
retrieval
sounding
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Summary:We introduce a new hyperspectral microwave remote sensing modality for atmospheric sounding, driven by recent advances in microwave device technology that now permit receiver arrays that can multiplex multiple broad frequency bands into more than ~ 100 spectral channels, thus improving both the vertical and horizontal resolution of the retrieved atmospheric profile. Global simulation studies over ocean and land in clear and cloudy atmospheres using three different atmospheric profile databases are presented that assess the temperature, moisture, and precipitation sounding capability of several notional hyperspectral systems with channels sampled near the 50-60-GHz, 118.75-GHz, and 183.31-GHz absorption lines. These analyses demonstrate that hyperspectral microwave operation using frequency multiplexing techniques substantially improves temperature and moisture profiling accuracy, especially in atmospheres that challenge conventional non-hyperspectral microwave sounding systems because of high water vapor and cloud liquid water content. Retrieval performance studies are also included that compare hyperspectral microwave sounding performance to conventional microwave and hyperspectral infrared approaches, both in a geostationary and low-earth orbit context, and a path forward to a new generation of high-performance all-weather sounding is discussed.
ISSN:2153-6996
2153-7003
DOI:10.1109/IGARSS.2010.5654299