A Spatial Downscaling Approach for WindSat Satellite Sea Surface Wind Based on Generative Adversarial Networks and Dual Learning Scheme

Liu, Jia; Sun, Y.; Ren, Kaijun; Zhao, Yue; Deng, Kefeng; Wang, Lizhe

doi:10.3390/rs14030769

Cited by 5 publications

(1 citation statement)

References 47 publications

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“…This level represents either a new variable type of data that has been derived from previously obtained satellite data (e.g., ocean primary productivity data are derived from chl a data [26]) or satellite data that have been augmented in some way [26]. This augmentation can be achieved via an increase in spatial resolution [155,[159][160][161], or, more popularly as will be showcased in Section 4, via missing data reconstruction. Some of the reviewed articles utilised level 4 data for gap-filling proof-of-concept purposes [162][163][164].…”

Section: Levels Of Datamentioning

confidence: 99%

Reconstruction Methods in Oceanographic Satellite Data Observation—A Survey

Ćatipović

Matić

Kalinić

2023

JMSE

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Oceanographic parameters, such as sea surface temperature, surface chlorophyll-a concentration, sea surface ice concentration, sea surface height, etc., are listed as Essential Climate Variables. Therefore, there is a crucial need for persistent and accurate measurements on a global scale. While in situ methods tend to be accurate and continuous, these qualities are difficult to scale spatially, leaving a significant portion of Earth’s oceans and seas unmonitored. To tackle this, various remote sensing techniques have been developed. One of the more prominent ways to measure the aforementioned parameters is via satellite spacecraft-mounted remote sensors. This way, spatial coverage is considerably increased while retaining significant accuracy and resolution. Unfortunately, due to the nature of electromagnetic signals, the atmosphere itself and its content (such as clouds, rain, etc.) frequently obstruct the signals, preventing the satellite-mounted sensors from measuring, resulting in gaps—missing data—in satellite recordings. One way to deal with these gaps is via various reconstruction methods developed through the past two decades. However, there seems to be a lack of review papers on reconstruction methods for satellite-derived oceanographic variables. To rectify the lack, this paper surveyed more than 130 articles dealing with the issue of data reconstruction. Articles were chosen according to two criteria: (a) the article has to feature satellite-derived oceanographic data (b) gaps in satellite data have to be reconstructed. As an additional result of the survey, a novel categorising system based on the type of input data and the usage of time series in reconstruction efforts is proposed.

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Section: Levels Of Datamentioning

confidence: 99%

Reconstruction Methods in Oceanographic Satellite Data Observation—A Survey

Ćatipović

Matić

Kalinić

2023

JMSE

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On the modern deep learning approaches for precipitation downscaling

et al. 2023

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Deep Learning (DL) based downscaling has become a popular tool in earth sciences recently.Increasingly, different DL approaches are being adopted to downscale coarser precipitation data and generate more accurate and reliable estimates at local (~ few km or even smaller) scales. Despite several studies adopting dynamical or statistical downscaling of precipitation, the accuracy is limited by the availability of ground truth. A key challenge to gauge the accuracy of such methods is to compare the downscaled data to point-scale observations which are often unavailable at such small scales. In this work, we carry out the DL-based downscaling to estimate the local precipitation data from the India Meteorological Department (IMD), which was created by approximating the value from station location to a grid point. To test the e cacy of different DL approaches, we apply four different methods of downscaling and evaluate their performance. The considered approaches are (i) Deep Statistical Downscaling (DeepSD), augmented Convolutional Long Short Term Memory (ConvLSTM), fully convolutional network (U-NET), and Super-Resolution Generative Adversarial Network (SR-GAN). A custom VGG network, used in the SR-GAN, is developed in this work using precipitation data. The results indicate that SR-GAN is the best method for precipitation data downscaling. The downscaled data is validated with precipitation values at IMD station. This DL method offers a promising alternative to statistical downscaling.

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