Abstract
The authors address the problem of evaluating the normalised radar cross-section (NRCS) of the sea surface perturbed by the joint effect of rain and wind, when observed close to nadir. They present a model, based on the full wave theory, for evaluating such an NRCS when varying polarisation, frequency and incidence angle (not far from nadir) for different values of wind velocity and of the root mean square height of the corrugation induced by rainfall. Some comparisons are made with the integral equation model results in the case of rain-induced corrugation alone. The two models are found to be in good agreement. In addition, partial comparisons made with experimental data suggest that the proposed model is well grounded and exploitable for application. It is indeed expected that the model can be exploited to improve precipitation measurements over the sea through spaceborne rain radar and to improve wind measurements using scatterometers in the presence of rain.
Highlights
Signals backscattered by the sea depend on several physical phenomena, but mainly on wind- and rainfallinduced corrugation
We report here the normalised radar cross section (NRCS) computed through the full wave model (FWM) in the case of a sea surface perturbed by rain only, for different values of frequency, incidence angle and rms height
The characterisation of the NRCS of the sea surface, when perturbed by rainfall only and by the joint action of wind and rainfall was the main objective of this paper
Summary
Signals backscattered by the sea depend on several physical phenomena, but mainly on wind- and rainfallinduced corrugation. While the influence of wind on sea normalised radar cross section (NRCS) has been investigated in depth, the effects of rainfall are not yet well known. It has been shown they are not negligible [l]. In principle, given a suitable analytical model (possibly taking advantage of specific experimental results) to represent changes of the NRCS of the water surface under the effect of rainfall, rainfall intensity could just be retrieved by measuring the sea NRCS. As shown in the companion paper [2], such a model can be exploited to improve the estimate of vertical profiles of rainfall rate through spaceborne weather radar.
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