Applications of Spectral Microwave Radiometry to Sensing of Sea Ice and the Ocean Surface.

The dielectric properties and emissivity of several types of sea ice were studied to improve upon the currently available algorithms for interpreting polar radiometric imagery from the SSM/I sensor. Laboratory studies indicated that the relative dielectric constant of new sea ice, as measured with a...

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Bibliographic Details
Main Author: St Germain, Karen M.
Other Authors: MASSACHUSETTS UNIV AMHERST DEPT OF ELECTRICAL AND COMPUTER ENGINEERING
Format: Text
Language:English
Published: 1993
Subjects:
Physical and Dynamic Oceanography
Snow
Ice and Permafrost
Meteorology
Non-radio Communications
*POLAR REGIONS
*OCEAN SURFACE
*MONITORING
*MICROWAVE EQUIPMENT
*RADIOMETRY
*SEA ICE
*REMOTE SENSING
*SATELLITE METEOROLOGY
ALGORITHMS
GROUND LEVEL
CLOUDS
UNCERTAINTY
LABORATORY TESTS
MODIFICATION
PARAMETERS
WATER
WIND
ATMOSPHERIC TEMPERATURE
THESES
ICE FORMATION
ESTIMATES
VARIABLES
DIELECTRIC PROPERTIES
BRIGHTNESS
SPECTRA
IMAGES
ATTENUATION
NOISE
LINKAGES
SURFACE TEMPERATURE
LOW FREQUENCY
OPEN WATER
C BAND
EMISSIVITY
SPECTRORADIOMETERS
WEATHER CORRECTING DECISION ALGORITHM
Ice
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA289138
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA289138
Description
Summary:The dielectric properties and emissivity of several types of sea ice were studied to improve upon the currently available algorithms for interpreting polar radiometric imagery from the SSM/I sensor. Laboratory studies indicated that the relative dielectric constant of new sea ice, as measured with a spectral C-Band radiometer, is approximately 12. This value represents the early stages of ice formation, and decreases rapidly with ice growth to approach the accepted value of 3.2 for first year ice. Atmospheric effects on satellite based passive microwave data were also examined with regard to the 19, 22, 37, and 85 GHz channels of the SSM/I system. The atmospheric vapor and cloud liquid water attenuation was empirically modeled with respect to frequency and atmospheric temperature. The mean atmospheric temperature was empirically linked to surface temperature through an exponential relationship. The surface emissivity was then modelled as a function of surface type via a mixing formalism, where the emissivity of open water depends on surface wind-speed. With the significant environmental variables parameterized, two algorithms for analysis of polar SSM/I data were developed. The first is a simple modification that adds the capability of determining ice temperature to an existing algorithm. The second is a weather correcting algorithm significantly more complex than those currently in use for the lower three frequencies of the Special Sensor Microwave Imager (SSM/I). The uncertainty of the six products due to measurement noise was estimated at 5% for surface parameters and 10% for atmospheric variables.

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