TY - JOUR
T1 - Wavelet-Based 2-D Sea Surface Reconstruction Method From Nearshore X-Band Radar Image Sequences
AU - Chernyshov, Pavel
AU - Vrecica, Teodor
AU - Nauri, Sara
AU - Toledo, Yaron
N1 - Publisher Copyright:
© 1980-2012 IEEE.
PY - 2022
Y1 - 2022
N2 - A 2-D wavelet-based radar analysis method for sea surface reconstruction is presented. The wavelet-based sea surface reconstruction (WSSR) method resolves the traditional limitations of the Fourier analysis, such as the requirement of the homogeneity and the periodicity of the analyzed image sequences, which is hardly found in nearshore wave shoaling conditions. The method is based on a filtration of the corresponding 2-D wavelet spectra of the radar images in the pseudo-wavevector domain and includes bandpass filtration and phase correction as well as the application of an empirical modulation transfer function. In extending the method to 2-D images, the main numerical and computational challenge is to realize the inverse wavelet transform. This challenge is overcome by using the Dirac delta function as a mother wavelet in the synthesis step to reduce the computational requirements of the integration procedures via an analytical solution. A statistical comparison between the original and the reconstructed surface elevations shows the mean absolute error on the level of 6%-14% of the significant wave height, which is quite an improvement when compared with conventional 2-D Fourier-based techniques (≈ 27% for the tested case). Another main advantage of the WSSR method is its near real-time capabilities, as it can work on a single or a small number of images unlike conventional methods, which require a few minutes of integration time. In addition to various synthetic data consistency checks, the WSSR was employed on real radar data collected in Haifa bay, Israel, with good qualitative agreements in comparison with a near wave buoy.
AB - A 2-D wavelet-based radar analysis method for sea surface reconstruction is presented. The wavelet-based sea surface reconstruction (WSSR) method resolves the traditional limitations of the Fourier analysis, such as the requirement of the homogeneity and the periodicity of the analyzed image sequences, which is hardly found in nearshore wave shoaling conditions. The method is based on a filtration of the corresponding 2-D wavelet spectra of the radar images in the pseudo-wavevector domain and includes bandpass filtration and phase correction as well as the application of an empirical modulation transfer function. In extending the method to 2-D images, the main numerical and computational challenge is to realize the inverse wavelet transform. This challenge is overcome by using the Dirac delta function as a mother wavelet in the synthesis step to reduce the computational requirements of the integration procedures via an analytical solution. A statistical comparison between the original and the reconstructed surface elevations shows the mean absolute error on the level of 6%-14% of the significant wave height, which is quite an improvement when compared with conventional 2-D Fourier-based techniques (≈ 27% for the tested case). Another main advantage of the WSSR method is its near real-time capabilities, as it can work on a single or a small number of images unlike conventional methods, which require a few minutes of integration time. In addition to various synthetic data consistency checks, the WSSR was employed on real radar data collected in Haifa bay, Israel, with good qualitative agreements in comparison with a near wave buoy.
KW - Individual wave retrieval
KW - X-band radar
KW - shoaling waves
KW - wavelet analysis
UR - http://www.scopus.com/inward/record.url?scp=85125724596&partnerID=8YFLogxK
U2 - 10.1109/TGRS.2022.3155352
DO - 10.1109/TGRS.2022.3155352
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AN - SCOPUS:85125724596
SN - 0196-2892
VL - 60
JO - IEEE Transactions on Geoscience and Remote Sensing
JF - IEEE Transactions on Geoscience and Remote Sensing
M1 - 511131
ER -