Modeling and Measuring Millimeter-Wave Scattering from Snow-Covered Terrain

A radiative transfer model was developed for characterizing radar backscatter from snow- covered ground at millimeter wave-lengths. The model was used to evaluate the radar response to incidence angle, snow depth, snow surface roughness, and snow liquid water content, for both like- and cross-polari...

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Bibliographic Details
Main Authors: Ulaby, Fawwaz T., Kuga, Yasuo, Austin, Richard
Other Authors: MICHIGAN UNIV ANN ARBOR DEPT OF ELECTRICAL ENGINEERING AND COMPUTER SCIENCE
Format: Text
Language:English
Published: 1991
Subjects:
Active & Passive Radar Detection & Equipment
Snow
Ice and Permafrost
*RADAR
*RADIATIVE TRANSFER
*SNOW
*ANGLE OF INCIDENCE
AGREEMENTS
ANGLES
ANTENNAS
BEHAVIOR
COMPARISON
CONFIGURATIONS
CROSS POLARIZATION
CYCLES
DEPTH
EXPERIMENTAL DATA
LAYERS
LIQUIDS
MICHIGAN
MILLIMETER WAVES
MODELS
POLARIZATION
PROFILES
RESPONSE
ROUGHNESS
SCATTEROMETERS
SEASONS
SURFACE ROUGHNESS
TILES
TRANSFER
TRUCKS
WATER
WINTER
BACKSCATTERING
DIELECTRIC PROPERTIES
SNOW COVER
ICE
TARGET DETECTION
MILITARY EQUIPMENT
Remote sensing
Ice
permafrost
Online Access:http://www.dtic.mil/docs/citations/ADP006381
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADP006381
Description
Summary:A radiative transfer model was developed for characterizing radar backscatter from snow- covered ground at millimeter wave-lengths. The model was used to evaluate the radar response to incidence angle, snow depth, snow surface roughness, and snow liquid water content, for both like- and cross-polarization configurations. The model behavior was compared with experimental observations made at 35, 95, and 140 GHz, including observations over diurnal cycles. The experimental data were acquired during the 1989 and 1990 winter seasons in Michigan using a truck-mounted millimeter-wave scatterometer system capable of observing the ground surface over a wide range of incidence angles for all linear combinations of transmit and receive antenna polarizations. Comparison of the measured data with model calculations revealed excellent agreement for dry snow as well as when the surface layer of the snowpack was wet. However, when the surface layer was dry and lower layers were wet, the model results were inconsistent with the radar observations. To deal with tile general case wherein the liquid water content exhibits a nonlinear profile with depth, a hybrid numerical-first order solution of the radiative transfer model was developed. This hybrid model provided excellent agreement with the diurnal observations of radar backscatter. This article is from Target and Clutter Scattering and Their Effects on Military Radar Performance (Diffraction par les Cibles et le Fouillis et ses Effets sur les Performances des Radars Militaires ), AD-A244 893, p9-1 thru 9-11.

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