Editorial Type:
Article
Article Type:
Research Article

Improved Polarimetric Calibration for Atmospheric Radars

Dmitri N. Moisseev IRCTR, Delft University of Technology, Delft, Netherlands

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Christine M. H. Unal IRCTR, Delft University of Technology, Delft, Netherlands

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Herman W. J. Russchenberg IRCTR, Delft University of Technology, Delft, Netherlands

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Leo P. Ligthart IRCTR, Delft University of Technology, Delft, Netherlands

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Print Publication:
01 Dec 2002
DOI:
https://doi.org/10.1175/1520-0426(2002)019<1968:IPCFAR>2.0.CO;2
Page(s):
1968–1977
Restricted access

Abstract

Polarization properties of radar waves that are scattered from atmospheric objects are of great interest in meteorological studies. However, polarimetric radar measurements are often not sufficiently accurate for retrieving physical properties of targets. To compensate for errors, radar polarimetric calibration is applied. Typical calibrations are performed based on measurements of point targets with known scattering matrices located in the boresight of the antenna. Such calibration takes into account the polarization state of the antenna pattern only at one point. Since radar measurements of atmospheric phenomena involve distributed targets that fill the full antenna beam, point target radar calibrations are inadequate for meteorological studies.

This paper explains in detail the effects of the complete antenna patterns on weather echoes. It is shown that the conventional polarimetric calibration can be significantly improved by incorporating light-rain (<20 dBZ) zenith-pointing measurements into the calibration procedure. As a result, the sensitivity of cross-polar measurements can be improved by 7 dB on average. Also it is shown that the bias in co-cross-polar correlation coefficient can be reduced.

Current affiliation: DEOS, Delft University of Technology, Delft, Netherlands

Corresponding author address: Dr. Dmitri N. Moisseev, DEOS, Delft University of Technology, Thijsseweg 11, 2629 JA Delft, Netherlands. Email: d.moisseev@citg.tudelft.nl

Abstract

Polarization properties of radar waves that are scattered from atmospheric objects are of great interest in meteorological studies. However, polarimetric radar measurements are often not sufficiently accurate for retrieving physical properties of targets. To compensate for errors, radar polarimetric calibration is applied. Typical calibrations are performed based on measurements of point targets with known scattering matrices located in the boresight of the antenna. Such calibration takes into account the polarization state of the antenna pattern only at one point. Since radar measurements of atmospheric phenomena involve distributed targets that fill the full antenna beam, point target radar calibrations are inadequate for meteorological studies.

This paper explains in detail the effects of the complete antenna patterns on weather echoes. It is shown that the conventional polarimetric calibration can be significantly improved by incorporating light-rain (<20 dBZ) zenith-pointing measurements into the calibration procedure. As a result, the sensitivity of cross-polar measurements can be improved by 7 dB on average. Also it is shown that the bias in co-cross-polar correlation coefficient can be reduced.

Current affiliation: DEOS, Delft University of Technology, Delft, Netherlands

Corresponding author address: Dr. Dmitri N. Moisseev, DEOS, Delft University of Technology, Thijsseweg 11, 2629 JA Delft, Netherlands. Email: d.moisseev@citg.tudelft.nl

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Cover Journal of Atmospheric and Oceanic Technology
Journal of Atmospheric and Oceanic Technology

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