Numerical study on signatures of atmospheric convective cells in radar images of the ocean
Numerical study on signatures of atmospheric convective cells in radar images of the ocean
Current and wind variations at the ocean surface can give rise to a modulation of the sea surface roughness and thus become visible in radar images. The discrimination between radar signatures of oceanic and atmospheric phenomena can be quite difficult, since signatures of different origin can have very similar shapes and magnitudes and are often superimposed upon each other. In this work we employ a numerical radar imaging model for an investigation of typical properties of radar signatures of atmospheric convective cells and of theoretical differences between such atmospherically induced radar signatures and those of oceanic phenomena. We show that main characteristics of observed multifrequency/multipolarization radar signatures of atmospheric convective cells over the Gulf Stream are reproduced quite well by the proposed model. This encourages us to vary wind and radar parameters systematically in order to get a general overview of the dependency of atmospherically induced radar signatures on these parameters. Finally, we compare typical characteristics of radar signatures of atmospheric and oceanic phenomena, and we present simulated radar images of a scenario of superimposed atmospheric convective cells and oceanic internal waves. We show that the proposed model supports the experimental finding that radar signatures of oceanic phenomena are stronger at horizontal (HH) than at vertical (VV) polarization, while atmospherically induced radar signatures are better visible at VV polarization.
remote sensing, synthetic aperture radar, convection, air-sea interaction
25707-25719
Ufermann, S.
19f2a5e8-f9e6-4cb2-a107-dcb021094cb1
Romeiser, R.
bd04441f-1b10-446e-bcc0-b8b209c14075
November 1999
Ufermann, S.
19f2a5e8-f9e6-4cb2-a107-dcb021094cb1
Romeiser, R.
bd04441f-1b10-446e-bcc0-b8b209c14075
Ufermann, S. and Romeiser, R.
(1999)
Numerical study on signatures of atmospheric convective cells in radar images of the ocean.
Journal of Geophysical Research, 104 (C11), .
Abstract
Current and wind variations at the ocean surface can give rise to a modulation of the sea surface roughness and thus become visible in radar images. The discrimination between radar signatures of oceanic and atmospheric phenomena can be quite difficult, since signatures of different origin can have very similar shapes and magnitudes and are often superimposed upon each other. In this work we employ a numerical radar imaging model for an investigation of typical properties of radar signatures of atmospheric convective cells and of theoretical differences between such atmospherically induced radar signatures and those of oceanic phenomena. We show that main characteristics of observed multifrequency/multipolarization radar signatures of atmospheric convective cells over the Gulf Stream are reproduced quite well by the proposed model. This encourages us to vary wind and radar parameters systematically in order to get a general overview of the dependency of atmospherically induced radar signatures on these parameters. Finally, we compare typical characteristics of radar signatures of atmospheric and oceanic phenomena, and we present simulated radar images of a scenario of superimposed atmospheric convective cells and oceanic internal waves. We show that the proposed model supports the experimental finding that radar signatures of oceanic phenomena are stronger at horizontal (HH) than at vertical (VV) polarization, while atmospherically induced radar signatures are better visible at VV polarization.
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UfermannRomeiser_JGR_1999JC900224.pdf
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Published date: November 1999
Keywords:
remote sensing, synthetic aperture radar, convection, air-sea interaction
Identifiers
Local EPrints ID: 9895
URI: http://eprints.soton.ac.uk/id/eprint/9895
ISSN: 0148-0227
PURE UUID: 6c672ec9-a2cf-4cba-a974-0dca923267c9
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Date deposited: 15 Oct 2004
Last modified: 15 Mar 2024 04:57
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Author:
S. Ufermann
Author:
R. Romeiser
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