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Estimating subpixel turbulent heat flux over leads from MODIS thermal infrared imagery with deep learning

Zhixiang Yin, Xiaodong Li, Yong Ge, Cheng Shang, Xinyan Li, Yun Du, Feng Ling

2021˜The œcryosphere10 citationsDOIOpen Access PDF

Abstract

Abstract. The turbulent heat flux (THF) over leads is an important parameter for climate change monitoring in the Arctic region. THF over leads is often calculated from satellite-derived ice surface temperature (IST) products, in which mixed pixels containing both ice and open water along lead boundaries reduce the accuracy of calculated THF. To address this problem, this paper proposes a deep residual convolutional neural network (CNN)-based framework to estimate THF over leads at the subpixel scale (DeepSTHF) based on remotely sensed images. The proposed DeepSTHF provides an IST image and the corresponding lead map with a finer spatial resolution than the input IST image so that the subpixel-scale THF can be estimated from them. The proposed approach is verified using simulated and real Moderate Resolution Imaging Spectroradiometer images and compared with the conventional cubic interpolation and pixel-based methods. The results demonstrate that the proposed CNN-based method can effectively estimate subpixel-scale information from the coarse data and performs well in producing fine-spatial-resolution IST images and lead maps, thereby providing more accurate and reliable THF over leads.

Topics & Concepts

Subpixel renderingConvolutional neural networkModerate-resolution imaging spectroradiometerImage resolutionPixelArtificial intelligenceRemote sensingComputer scienceInterpolation (computer graphics)Scale (ratio)Deep learningResidualComputer visionSatellitePattern recognition (psychology)GeologyImage (mathematics)AlgorithmPhysicsAstronomyQuantum mechanicsUrban Heat Island MitigationMeteorological Phenomena and SimulationsCryospheric studies and observations
Estimating subpixel turbulent heat flux over leads from MODIS thermal infrared imagery with deep learning | Litcius