A Modeling Study of the Impact of the Sea Surface Temperature on the Backscattering Coefficient and Wind Field Retrieval

Peng, Yihuan; Xie, Xuetong; Lin, Mingsen; Pan, Cuihong; Li, Haitao

doi:10.1109/access.2020.2990160

Cited by 3 publications

(3 citation statements)

References 32 publications

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“…Then, the wind direction of ECMWF was compared with the reference wind speed and wind direction of L2B, and the data with a large deviation were eliminated. The wind speed accuracy was ±2 m/s, and the wind direction accuracy was ±20 • [23,24]. In addition, because of the large amount of the matched data, one-sixth of the data from each month were randomly selected to form a new raw data set.…”

Section: Data Preprocessingmentioning

confidence: 99%

A Study of Sea Surface Rain Identification Based on HY-2A Scatterometer

et al. 2021

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Rain affects the wind measurement accuracy of the Ku-band spaceborne scatterometer. In order to improve the quality of the retrieved wind field, it is necessary to identify and flag rain-contaminated data. In this study, an HY-2A scatterometer is used to study rain identification. In addition to the conventional parameters, such as the retrieved wind speed, the wind direction relative to the along-track direction, and the normalized beam difference, the experiment expands the mean deviation of the backscattering coefficient, the beam difference between fore and aft, and the node number of the wind vector cell (WVC) as the sensitive parameters according to the microwave scattering characteristics of rain and the actual measurement situation of the HY-2A. Furthermore, a rain identification model for HY2 (HY2RRM) with the K-Nearest Neighborhood (KNN) algorithm was built. After several tests, the accuracy of the selected HY2RRM approach is found to about 88%, and about 70% of rain-contaminated data can be accurately identified. The research results are helpful for better understanding the characteristics of microwave backscattering and provide a possible way to further improve the wind field retrieval accuracy of the HY-2A scatterometer and other Ku-band scatterometers.

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Section: Data Preprocessingmentioning

confidence: 99%

A Study of Sea Surface Rain Identification Based on HY-2A Scatterometer

et al. 2021

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“…Many scatterometers and radar missions have observed the ocean in space, such as Microwave Imaging Radiometer with Aperture Synthesis (MIRAS) on the ESA SMOS satellite, Lband microwave radiometer on NASA's Aquarius satellite, phased array L-band synthetic aperture radar (PALSAR) on Japan's ALOS satellite, Deutsche Aerospace's TerraSAR-X radar satellite and the microwave scatterometers on China's HaiYang-2 (HY-2) satellites. Based on certain inversion models, some marine environmental parameters, such as ocean wind vector, sea surface salinity/temperature, sea surface height, and so on, can be obtained from the observation data [1][2][3][4]. General, the inversion accuracy strictly relies on the electromagnetic (EM) scattering models of rough sea surfaces, which mainly include the empirical models and the physical models.…”

Section: Introductionmentioning

confidence: 99%

“…Then, this criterion was used by Liu et al in FASTEM-4 [4]. Furthermore, Li et al (2020) proposed an adaptive cutoff wavenumber by making the measured sea surface roughness equal to the root mean square height of the small-scale sea surface spectrum [23]. Based on the assumption that the physical optical integral is asymptotically "α-stable distribution" under high frequency limit conditions, Johnson et al (2022) proposed a cutoff wavenumber model that depends on frequency, spectrum, and incident angle.…”

Section: Introductionmentioning

confidence: 99%

Quantitative Research of Cutoff Wavenumber and Wave Spectrum for Electromagnetic Scattering Computation with Two-Scale Method

Guo,

2023

Preprint

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The two-scale method (TSM) is an effective approach to simulate electromagnetic (EM) scattering from rough sea surface, to interpret physical interaction of EM wave with rough sea surfaces. The sea surface roughness spectrum and the cutoff wavenumber are two key factors affecting the accuracy of TSM simulation. This paper takes the geophysical model functions (GMFs) of different band as reference, and quantitatively studies the two factors based on the numerical simulation of different polarization backscattering coefficients. The numerical simulation demonstrates that Apel spectrum is more suitable for the backscattering simulation in C/X/Ku-band, and the optimal cutoff wavenumbers are also derived for TSM simulation of EM scattering in C/X/Ku-band. Then an empirical model function of optimal cutoff wavenumbers with respect to frequency, incident angle and wind speed are obtained with regression method. Finally, the simulation results with the new model function of cutoff wavenumber are compared with the GMF and measured data in different bands and they are all consistent. Moreover, a physical explanation for the optimal cutoff wavenumber is also given.

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A Backscattering Model of Rain-Affected Sea Surface With Two-Scale Method

Ye,

Guo

2024

IEEE Trans. Geosci. Remote Sensing

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A Modeling Study of the Impact of the Sea Surface Temperature on the Backscattering Coefficient and Wind Field Retrieval

Cited by 3 publications

References 32 publications

A Study of Sea Surface Rain Identification Based on HY-2A Scatterometer

A Study of Sea Surface Rain Identification Based on HY-2A Scatterometer

Quantitative Research of Cutoff Wavenumber and Wave Spectrum for Electromagnetic Scattering Computation with Two-Scale Method

A Backscattering Model of Rain-Affected Sea Surface With Two-Scale Method

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