His primary areas of investigation include Remote sensing, Hyperspectral imaging, Optics, Ocean color and Absorption. His studies in Remote sensing integrate themes in fields like Attenuation and Satellite. Curtiss O. Davis interconnects Stray light, Spectrometer, Imaging spectrometer, Bathymetry and Radiative transfer in the investigation of issues within Hyperspectral imaging.
His Imaging spectrometer research is multidisciplinary, incorporating elements of Phytoplankton, Colored dissolved organic matter and Spectral resolution. His work carried out in the field of Optics brings together such families of science as Image quality and Spectrograph. He has included themes like Climatology, Geosynchronous orbit, Atmospheric correction, Meteorology and Biogeochemistry in his Ocean color study.
The scientist’s investigation covers issues in Remote sensing, Hyperspectral imaging, Meteorology, Ocean color and Imaging spectrometer. The Remote sensing study combines topics in areas such as Atmospheric correction, Spectrometer, Bathymetry and Physical oceanography. His study looks at the intersection of Spectrometer and topics like Spectral imaging with Imaging spectroscopy.
His Hyperspectral imaging research includes themes of International Space Station, Optics, Remote sensing, Satellite and Oceanography. His studies deal with areas such as Vegetation and Radiometry as well as Meteorology. His Ocean color study combines topics in areas such as Image resolution, Radiometric dating, Geostationary orbit, SeaWiFS and Algorithm.
Curtiss O. Davis spends much of his time researching Remote sensing, Ocean color, Hyperspectral imaging, Meteorology and Oceanography. His Remote sensing research incorporates themes from Satellite, Bathymetry, Physical oceanography and Imaging spectrometer. His study in Ocean color is interdisciplinary in nature, drawing from both Radiometric dating, Upwelling and Red tide.
His research in Hyperspectral imaging intersects with topics in Spectrometer and Optics. His work deals with themes such as International Space Station, Atmospheric correction, Radiance, Coastal zone and Visible Infrared Imaging Radiometer Suite, which intersect with Meteorology. He combines subjects such as Phytoplankton and Remotely sensing with his study of Oceanography.
His primary areas of study are Ocean color, Remote sensing, Oceanography, Meteorology and Phytoplankton. His study looks at the relationship between Ocean color and fields such as Geostationary orbit, as well as how they intersect with chemical problems. His work on Hyperspectral imaging as part of general Remote sensing research is frequently linked to Context, bridging the gap between disciplines.
His work in Hyperspectral imaging covers topics such as Atmospheric correction which are related to areas like International Space Station and Radiometric calibration. His work in the fields of Oceanography, such as Bay, intersects with other areas such as Discharge, Seascapes and Ocean gyre. His Meteorology research also works with subjects such as
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Atmospheric correction algorithms for hyperspectral remote sensing data of land and ocean
Bo-Cai Gao;Marcos J. Montes;Curtiss O. Davis;Alexander F.H. Goetz.
Remote Sensing of Environment (2009)
Model for the interpretation of hyperspectral remote-sensing reflectance.
Zhongping Lee;Kendall L. Carder;Steve K. Hawes;Robert G. Steward.
Applied Optics (1994)
Ocean Color Remote Sensing of Seagrass and Bathymetry in the Bahamas Banks by High-Resolution Airborne Imagery
Heidi M. Dierssen;Richard C. Zimmerman;Robert A. Leathers;T. Valerie Downes.
Limnology and Oceanography (2003)
Euphotic zone depth: Its derivation and implication to ocean-color remote sensing
Zhong Ping Lee;Alan Weidemann;John Kindle;Robert Arnone.
Journal of Geophysical Research (2007)
Interpretation of hyperspectral remote-sensing imagery by spectrum matching and look-up tables
Curtis D. Mobley;Lydia K. Sundman;Curtiss O. Davis;Jeffrey H. Bowles.
Applied Optics (2005)
Atmospheric correction algorithm for hyperspectral remote sensing of ocean color from space
Bo-Cai Gao;Marcos J. Montes;Ziauddin Ahmad;Curtiss O. Davis.
Applied Optics (2000)
Diffuse attenuation coefficient of downwelling irradiance: An evaluation of remote sensing methods
Zhong-Ping Lee;Zhong-Ping Lee;Miroslaw Darecki;Kendall L. Carder;Curtiss O. Davis.
Journal of Geophysical Research (2005)
Photosynthetic characteristics and estimated growth rates indicate grazing is the proximate control of primary production in the equatorial Pacific
John J. Cullen;Marlon R. Lewis;Curtiss O. Davis;Richard T. Barber.
Journal of Geophysical Research (1992)
Ocean PHILLS hyperspectral imager: design, characterization, and calibration
Curtiss Davis;Jeffrey Bowles;Robert A. Leathers;Daniel R. Korwan.
Optics Express (2002)
Method to derive ocean absorption coefficients from remote-sensing reflectance
Z. P. Lee;K. L. Carder;T. G. Peacock;C. O. Davis.
Applied Optics (1996)
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