Improvement of Split-Window Algorithm for Land Surface Temperature Retrieval from Sentinel-3A SLSTR Data Over Barren Surfaces Using ASTER GED Product

Zhang, Shuting; Duan, Si‐Bo; Li, Zhao-Liang; Huang, Cheng; Wu, Hua; Han, Xiao-Jing; Leng, Pei; Gao, Maofang

doi:10.3390/rs11243025

Cited by 19 publications

(19 citation statements)

References 46 publications

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“…where , ′ and , ′ represent the generated BT and FVC, respectively; and represent the mean and standard deviation, respectively; and , −1 represents an inverse process of the Planck function from thermal radiance to BT. According to the uncertainty analysis in [30,45], the uncertainties associated with the angular variations in LST retrieval were considered by setting to 0.25 K and 0.75 K with = 0. Based on [46], angular errors in FVC were included by setting to 0 and to 0.03 and 0.09.…”

Section: ) Retrieval Noisementioning

confidence: 99%

“…where 0 − 7 are the SW coefficients; 8 and 9 represent the top-of-atmosphere BTs in SLSTR channels 8 (10.85 μm) and 9 (12.0 μm), respectively; and ̅ and are the mean and the differences of emissivity 8, and 9, in SLSTR channels 8 and 9, respectively. In-depth details on the SW algorithm are readily found in the published literature [28,30,45,48]. The SW coefficients were determined by fitting (11) to a synthetic dataset obtained with MODTRAN 5.2 [49] for data from the ASTER spectral library [50] and Seebor V5.2 atmosphere profile library [51]: we used 81 emissivity spectra, including for natural samples of vegetation, water, ice, snow, rock, sand and soil, and 4948 daytime atmospheric profiles to obtain a globally representative data collection.…”

Section: B Atmospheric Correctionmentioning

confidence: 99%

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Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations

Bian

Göttsche

et al. 2020

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Land surface component temperatures (LSCTs), i.e., the temperatures of soil and vegetation, are important parameters in many applications, such as estimating evapotranspiration and monitoring droughts. However, the multi-angle algorithm is affected due to different spatial resolution between nadir and oblique views. Therefore, we propose a combined retrieval algorithm that uses dual-angle and multi-pixel observations together. The Sea and Land Surface Temperature Radiometer (SLSTR) onboard ESA's Sentinel-3 satellite allows for quasi-synchronous dual-angle observations, from which LSCTs can be retrieved using dualangle and multi-pixel algorithms. The better performance of the combined algorithm is demonstrated using a sensitivity analysis based on a synthetic dataset. The spatial errors in oblique view due to different spatial resolution can reach 4.5 K and have a large effect on the multi-angle algorithm. The introduction of multi-pixel information in a window can reduce the effect of such spatial errors, and the retrieval results of LSCTs can be further improved by using multi-angle information for a pixel. In the validation, the proposed combined algorithm performed better, with LSCT root mean squared errors (RMSEs) of 3.09 K and 1.91 K for soil and vegetation at a grass site, respectively, and corresponding values of 3.71 K and 3.42 K at a sparse forest site, respectively. Considering that the temperature differences between components can reach 20 K, the results confirm that, in addition to a pixelaverage LST, the combined retrieval algorithm can provide information on LSCTs. This article demonstrates the potential of utilizing additional information sources for better LSCT results, which makes the presented combined strategy a promising option for deriving large-scale LSCT products.

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Section: ) Retrieval Noisementioning

confidence: 99%

Section: B Atmospheric Correctionmentioning

confidence: 99%

Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations

Bian

Göttsche

et al. 2020

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…Several validations have shown that this emissivity product has high accuracy over bare soil surface in arid and semi-arid lands [44], [45]. Therefore, to characterize the variation of bare soil emissivity relatively accurately, this dataset has been used in emissivity estimation for many satellites sensors [46]- [49].…”

Section: Introductionmentioning

confidence: 99%

Retrieving Land Surface Temperature From Chinese FY-3D MERSI-2 Data Using an Operational Split Window Algorithm

Tang

Zhu

et al. 2021

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…Currently, most land surface temperature and sea surface temperature (LST and SST, respectively) products are based on multichannel methods. The split-window (SW) algorithm is widely used for TIR sensors, as it is easy to apply and can be used without extensive computation of radiative transfer models (RTMs) or explicit information of atmospheric conditions [1,[6][7][8][9]. However, these multi-channel methods have limited application in other types of single-channel-based IR sensors, such as LANDSAT-7 [10].…”

Section: Introductionmentioning

confidence: 99%

An Atmospheric Correction Using High Resolution Numerical Weather Prediction Models for Satellite-Borne Single-Channel Mid-Wavelength and Thermal Infrared Imaging Sensors

2020

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This paper presents a single-channel atmospheric correction method for remotely sensed infrared (wavelength of 3–15 μm) images with various observation angles. The method is based on basic radiative transfer equations with a simple absorption-focused regression model to calculate the optical thickness of each atmospheric layer. By employing a simple regression model and re-organization of atmospheric profiles by considering viewing geometry, the proposed method conducts atmospheric correction at every pixel of a numerical weather prediction model in a single step calculation. The Visible Infrared Imaging Radiometer Suite (VIIRS) imaging channel (375 m) I4 (3.55~3.93 μm) and I5 (10.50~12.40 μm) bands were used as mid-wavelength and thermal infrared images to demonstrate the effectiveness of the proposed single-channel atmospheric correction method. The estimated sea surface temperatures (SSTs) obtained by the proposed method with high resolution numerical weather prediction models were compared with sea-truth temperature data from ocean buoys, multichannel-based SST products from VIIRS/MODIS, and results from MODerate resolution atmospheric TRANsmission 5 (MODTRAN 5), for validation. High resolution (1.5 km and 12 km) numerical weather prediction (NWP) models distributed by the Korea Meteorological Administration (KMA) were employed as input atmospheric data. Nighttime SST estimations with the I4 band showed a root mean squared error (RMSE) of 0.95 °C, similar to that of the VIIRS product (RMSE: 0.92 °C) and lower than that of the MODIS product (RMSE: 1.74 °C), while estimations with the I5 band showed an RMSE of 1.81 °C. RMSEs from MODTRAN simulations were similar (within 0.2 °C) to those of the proposed method (I4: 0.81 °C, I5: 1.67 °C). These results demonstrated the competitive performance of a regression-based method using high-resolution numerical weather prediction (NWP) models for atmospheric correction of single-channel infrared imaging sensors.

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Improvement of Split-Window Algorithm for Land Surface Temperature Retrieval from Sentinel-3A SLSTR Data Over Barren Surfaces Using ASTER GED Product

Cited by 19 publications

References 46 publications

Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations

Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations

Retrieving Land Surface Temperature From Chinese FY-3D MERSI-2 Data Using an Operational Split Window Algorithm

An Atmospheric Correction Using High Resolution Numerical Weather Prediction Models for Satellite-Borne Single-Channel Mid-Wavelength and Thermal Infrared Imaging Sensors

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