Multi-Scale, Multi-Frequency, and Quad-Polarized Microwave Scattering from Sea Surface Numerical Simulation

Oceanic eddies play an important role in global energy and material transport, and contribute greatly to nutrient and phytoplankton distribution. Deep learning is employed to identify oceanic eddies from sea surface height anomalies data. In order to adapt to segmentation problems for multi-scale oceanic eddies, the pyramid scene parsing network (PSPNet), which is able to satisfy the fusion of semantics and details, is applied as the core algorithm in the eddy detection methods. The results of eddies identified from this artificial intelligence (AI) method are well compared with those from a traditional vector geometry-based (VG) method. More oceanic eddies are detected by the AI algorithm than the VG method, especially for small-scale eddies. Therefore, the present study demonstrates that the AI algorithm is applicable of oceanic eddy detection. It is one of the first few of efforts to bridge AI techniques and oceanography research.

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Time domain numerical simulation of microwave backscattering from sea surface for radar remote sensing

OCEANS'10 IEEE SYDNEY ◽

10.1109/oceanssyd.2010.5603838 ◽

2010 ◽

Author(s):

Takero Yoshida ◽

Chang-Kyu Rheem

Keyword(s):

Remote Sensing ◽

Numerical Simulation ◽

Time Domain ◽

Sea Surface ◽

Radar Remote Sensing

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Doppler Spectra of Microwave Backscatter From Water Surface

23rd International Conference on Offshore Mechanics and Arctic Engineering, Volume 3 ◽

10.1115/omae2004-51272 ◽

2004 ◽

Cited By ~ 2

Author(s):

Chang-Kyu Rheem ◽

Hidetaka Kobayashi ◽

Kazuomi Yamanishi

Keyword(s):

Water Surface ◽

Microwave Remote Sensing ◽

Close Relation ◽

Global Scale ◽

Experimental Results ◽

Sea Surface ◽

Surface Measurement ◽

Doppler Spectrum ◽

Microwave Scattering ◽

The Mean

This paper describes the experimental results of microwave backscattering at water surfaces. Active microwave remote sensing is one of the useful techniques for sea surface measurement. For example, it enables us to know the wind vector on global scale. A principle of measurement is that the microwave backscattering depends on the wind speed. Therefore understanding of the phenomena of microwave scattering at sea surface in detail is indispensable for improvement of measuring accuracy. The purpose of the research is to investigate the characteristics of microwave scattering at various water surface conditions. Water surface was generated by wind and currents, microwave backscattering at that surface was measured by X and C-band microwave scatterometer. The experimental results were summarized in scattering coefficients and Doppler spectra. X-band microwave was more sensitive at wind wave surface than C-band. The mean frequency of Doppler spectrum of backscattering microwave was corresponded to the phase velocity of the mean water surface wave and the bandwidth of Doppler spectrum had close relation to the orbital velocity of the mean wave. A current had no effect on the scattering coefficient, but the Doppler spectrum was shifted to the side corresponding to current direction.

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