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Your search keyword '"Qiankun Zhu"' showing total 8 results
Start Over Author "Qiankun Zhu" Publisher institute of electrical and electronics engineers (ieee)
8 results on '"Qiankun Zhu"'

2. Enhancing Spatial Resolution of Sea Surface Salinity in Estuarine Regions by Combining Microwave and Ocean Color Satellite Data

Author

Delu Pan, Yan Bai, Difeng Wang, Xuchen Jin, Qiankun Zhu, Fang Gong, and Xianqiang He

Subjects
geography, geography.geographical_feature_category, Oceanography, Ocean color, Satellite data, Environmental science, Estuary, Sea surface salinity, Electrical and Electronic Engineering, Geotechnical Engineering and Engineering Geology, Image resolution, Microwave
Published
2022
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4. Radiometric Calibration Scheme for COCTS/HY-1C Based on Image Simulation From the Standard Remote-Sensing Reflectance

Author

Jianqiang Liu, Jianyu Chen, Bangyi Tao, Qiankun Zhu, Jing Ding, Haiqing Huang, Zengzhou Hao, Zhihua Mao, and Peng Chen

Subjects
Scanner, Pixel, Ocean color, Data quality, Atmospheric correction, Calibration, General Earth and Planetary Sciences, Environmental science, Satellite, Electrical and Electronic Engineering, Radiometric calibration, Remote sensing
Abstract

The data quality of the satellite-retrieved water-leaving reflectance (Rrs) depends on the accuracy of radiometric calibration and the performance of atmospheric correction. A radiometric calibration scheme (RCS) has been developed to ensure the accuracy of Rrs through the gain adjustment factors (GAFs) to adjust the satellite calibrated data. The GAF is obtained from the ratio of the simulated reflectance at the top of atmosphere to the calibrated values. The simulated reflectance is computed by a satellite image simulation model (SISM) based on a dataset of climatological global Rrs images according to the same geometric angles of the image pixels. The dataset, taken as a kind of the pseudo-invariant calibration sites for in situ measurements, is generated from the average of standard satellite-retrieved Rrs during more than two decades (1997-2019). The SISM inputs the aerosol properties retrieved from the satellite level 1B data (L1B) and uses the same algorithms of the data-processing system. The results show that the accuracy of the calibration of the website downloaded Chinese Ocean Color and Temperature Scanner on the Haiyang-1C satellite (COCTS/HY-1C) is beyond the requirement of the operational data-processing system (higher than 10%). The daily GAFs can be used to recalibrate the L1B data and monitor the daily sensor degradations. The influences of GAFs are assessed on different meteorological conditions, indicating that the values decrease with the increase of the aerosol optical depths (AODs) but the average of the GAF image is little affected by the meteorological conditions. The uncertainty of GAFs was tested by the different inputs of Rrs values and the results show that they are actually little affected by errors of the Rrs inputs. Therefore, the RCS, taking the advantage of vicarious calibration, offers a tool to recalibrate the COCTS/HY-1C L1B data for the data reprocessing system.

Published
2022
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6. A Layer Removal Scheme for Atmospheric Correction of Satellite Ocean Color Data in Coastal Regions

Author

Bangyi Tao, Jianyu Chen, Zengzhou Hao, Peng Chen, Qiankun Zhu, Haiqing Huang, and Zhihua Mao

Subjects
0211 other engineering and technologies, Atmospheric correction, 02 engineering and technology, Atmospheric model, Physics::Geophysics, Atmosphere, symbols.namesake, Approximation error, Ocean color, Radiance, symbols, General Earth and Planetary Sciences, Environmental science, Satellite, Electrical and Electronic Engineering, Rayleigh scattering, Physics::Atmospheric and Oceanic Physics, 021101 geological & geomatics engineering, Remote sensing
Abstract

The radiance received by satellite sensors viewing the ocean is a mixed signal of the atmosphere and ocean. Accurate decomposition of the radiance components is crucial because any inclusion of atmospheric signal in the water-leaving radiance leads to an incorrect estimation of the oceanic parameters. This is especially true over the turbid coastal waters, where the estimation of the radiance components is difficult. A layer removal scheme for atmospheric correction (LRSAC) has been developed to take the atmospheric and oceanic components as the layer structure according to the sunlight passing in the Sun–Earth-satellite system. Compared with the normal coupled atmospheric column, the uncertainty of the layer structure of Rayleigh and aerosols has a relatively small error with a mean relative error (MRE) of 0.063%. As the aerosol layer was put between Rayleigh and ocean, a new Rayleigh lookup table (LUT) was regenerated using 6SV (Second Simulation of a Satellite Signal in the Solar Spectrum, Vector version 3.2) based on the zero reflectance at the ground to produce the pure Rayleigh reflectance without the Rayleigh–ocean interaction. The accuracy of the LRSAC was validated by in situ water-leaving reflectance, obtaining an MRE of 6.3%, a root-mean-square error (RMSE) of 0.0028, and the mean correlation coefficient of 0.86 based on 430 matchup pairs over the East China Sea. Results show that the LRSAC can be used to decompose the reflectance at the top of each layer for the atmospheric correction over turbid coastal waters.

Published
2021
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7. Radiometric Sensitivity and Signal Detectability of Ocean Color Satellite Sensor Under High Solar Zenith Angles

Author

Qiankun Zhu, Xianqiang He, Yan Bai, Palanisamy Shanmugam, Difeng Wang, Fang Gong, Hao Li, and Haiqing Huang

Subjects
Physics, Colored dissolved organic matter, Biogeochemical cycle, Ocean color, Temporal resolution, Geostationary orbit, General Earth and Planetary Sciences, Satellite, Sensitivity (control systems), Electrical and Electronic Engineering, Atmospheric sciences, Zenith
Abstract

New generation ocean color imagers on geostationary orbits are designed to provide a much higher temporal resolution along with enhanced spatial and spectral resolutions that will open up obvious opportunities for improving the sampling frequency and resolving diurnal variability of phytoplankton and other biogeochemical properties in dynamic coastal waters. Despite the capabilities of such new generation sensors to detect the diurnal cycles of various ocean phenomena, there is a lack of knowledge on their radiometric sensitivity and signal detectability for observing the ocean color at morning or evening hours. This paper aims to explore the capability of geostationary satellite ocean color sensor for detecting ocean biogeochemical properties [chlorophyll (CHL); total suspended matter (TSM); colored dissolved organic matter (CDOM)] under high solar zenith angles (SZAs). The analysis is based upon simulations from the vector radiative transfer model for the coupled ocean–atmosphere system (PCOART-SA), which considers the earth curvature effects. The unitless differential signal-to-noise ratio ( $\Delta $ SNR) is used as a discriminant parameter to indicate the radiometric sensitivity to variation of different biogeochemical properties. The results showed that the SZAs have a significant impact on the signal detectability for CHL variation. For typical shelf water (CHL $= 1\,\,\mu \text{g}$ /L, TSM = 1 mg/L, CDOM = 0.15 m−1), with the typical observation zenith angle (OZA) = 30°, changes on the order of $\Delta $ CHL $= 0.024\,\,\mu \text{g}$ /L (2.4% to background CHL) were detectable when SZA = 30°; when SZA > 75°, the detectable minimal $\Delta $ CHL increased to $0.77~\mu \text{g}$ /L (77%), indicating the difficulty of detecting CHL under high SZA. For CDOM, the detectability of changes ( $\Delta $ CDOM) was also found to be closely related to the SZAs, i.e., changes on the order of ten times depending on the SZA conditions. However, even under extremely high SZA conditions (SZA = 80°, OZA = 30°), $\Delta $ CDOM = 0.007 m−1 which is about 4.7% of the background CDOM was still detectable at 412 nm. On the other hand, under high SZA conditions (SZA = 80°, OZA = 30°), $\Delta $ TSM = 0.211 mg/L (2.1% to the background TSM) was also detectable. Overall, our results indicate that under high SZAs conditions, the geostationary satellite ocean color sensor may experience difficulty in detecting a slight change in CHL variation in productive waters, but it still can detect small changes in TSM and CDOM contents despite a reduced sensitivity at the steeper SZAs.

Published
2019
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8. Edge-Guided Multiscale Segmentation of Satellite Multispectral Imagery

Author

Zhihua Mao, Jianyu Chen, Qiankun Zhu, Jonathan Li, and Delu Pan

Subjects
Morphological gradient, Pixel, Segmentation-based object categorization, Computer science, business.industry, Multispectral image, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Scale-space segmentation, Pattern recognition, Image segmentation, Edge detection, Multispectral pattern recognition, Image texture, Computer Science::Computer Vision and Pattern Recognition, Canny edge detector, General Earth and Planetary Sciences, Computer vision, Segmentation, Artificial intelligence, Electrical and Electronic Engineering, Range segmentation, business, Physics::Atmospheric and Oceanic Physics, Image gradient, MathematicsofComputing_DISCRETEMATHEMATICS
Abstract

This paper presents a new approach to multiscale segmentation of satellite multispectral imagery using edge information. The Canny edge detector is applied to perform multispectral edge detection. The detected edge features are then utilized in a multiscale segmentation loop, and the merge procedure for adjacent image objects is controlled by a separability criterion that combines edge information with segmentation scale. The significance of the edge is measured by adjacent partitioned regions to perform edge assessment. The present method is based on a half-partition structure, which is composed of three steps: single edge detection, separated pixel grouping, and significant feature calculation. The spectral distance of the half-partitions separated by the edge is calculated, compared, and integrated into the edge information. The results show that the proposed approach works well on satellite multispectral images of a coastal area.

Published
2012
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