Cloud Detection for Satellite Imagery Using Attention-Based U-Net Convolutional Neural Network

Guo, Yanan; Cao, Xiaoqun; Liu, Bainian; Gao, Mei

doi:10.3390/sym12061056

Cited by 57 publications

(22 citation statements)

References 48 publications

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“…In addition, refinements were done on small patch masks rather than large masks of the entire Landsat 8 scenes. In another work, the authors of Cloud-AttU [51] employed a UNet model that is enriched with a specific attention module in its skip connections. Multiple attention modules enabled the model to learn proper features by paying attention to the most relevant locations in input training images or feature maps.…”

Section: Related Workmentioning

confidence: 99%

Cloud and Cloud Shadow Segmentation for Remote Sensing Imagery Via Filtered Jaccard Loss Function and Parametric Augmentation

Mohajerani

Saeedi

2021

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

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Cloud and cloud shadow segmentation are fundamental processes in optical remote sensing image analysis. Current methods for cloud/shadow identification in geospatial imagery are not as accurate as they should, especially in the presence of snow and haze. This paper presents a deep learningbased framework for the detection of cloud/shadow in Landsat 8 images. Our method benefits from a convolutional neural network, Cloud-Net+ (a modification of our previously proposed Cloud-Net [1]) that is trained with a novel loss function (Filtered Jaccard Loss). The proposed loss function is more sensitive to the absence of foreground objects in an image and penalizes/rewards the predicted mask more accurately than other common loss functions. In addition, a sunlight direction-aware data augmentation technique is developed for the task of cloud shadow detection to extend the generalization ability of the proposed model by expanding existing training sets. The combination of Cloud-Net+, Filtered Jaccard Loss function, and the proposed augmentation algorithm delivers superior results on four public cloud/shadow detection datasets. Our experiments on Pascal VOC dataset exemplifies the applicability and quality of our proposed network and loss function in other computer vision applications.

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Section: Related Workmentioning

confidence: 99%

Cloud and Cloud Shadow Segmentation for Remote Sensing Imagery Via Filtered Jaccard Loss Function and Parametric Augmentation

Mohajerani

Saeedi

2021

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

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“…Studies have demonstrated the potential for CNNs to enhance cloud detection using high-resolution (<100 m) LEO satellites such as Landsat-8. [40][41][42][43][44] One study had overall cloud detection accuracy of 97.05% from Landsat-8 images and provided examples of successful identification of clouds over snow and ice. 42 Some CNNs also distinguish between optically thin and thick clouds, 40,41 which would allow for special treatment of areas where the surface is visible.…”

Section: Optically Thin Cloudsmentioning

confidence: 99%

Extrapolating shortwave geostationary satellite imagery of clouds into nighttime using longwave observations

Rugg

Haggerty

Adriaansen

et al. 2021

J. Appl. Rem. Sens.

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The lack of shortwave (SW, visible, and near-infrared) geostationary satellite data at night results in degradation of many weather forecasts and real-time diagnostic products. We present a method to extrapolate SW GOES-16 advanced baseline imager data through night using nighttime longwave (LW, infrared) observations and the relationships between LW and SW data observed during the previous day. The method is not a forecast since it requires LW nighttime observations but can provide continuity through day, night, and satellite terminator hours. To provide performance statistics, the algorithm is applied during the day so the SW extrapolations can be compared to observations. Typical mean absolute errors (MAEs) range from 1.0% to 12.7% reflectance depending on the SW channel. These MAEs can be predicted using a diagnostic metric called 0-h MAE which quantifies the quality of the algorithm's input data. In addition to quantitative error statistics, three case studies are presented, including an animation of extrapolated imagery from dusk through dawn. Considerations for future improvements include use of convolutional neural networks and/or object-based extrapolations where mesoscale features are extrapolated individually. © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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“…Single-scene algorithms can utilize the spatial context through deep learning approaches. Deep cloud detection largely relies on the U-net architecture and has been shown to outperform the Fmask algorithm, [25,117,102]. The deep learning approach requires a large annotated data set.…”

Section: B2 Detecting Clouds In Satellite Imagesmentioning

confidence: 99%

Seeing Through Clouds in Satellite Images

Zhao

Olsen

Chandra

2021

Preprint

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This paper presents a neural-network-based solution to recover pixels occluded by clouds in satellite images. We leverage radio frequency (RF) signals in the ultra/super-high frequency band that penetrate clouds to help reconstruct the occluded regions in multispectral images. We introduce the first multi-modal multitemporal cloud removal model. Our model uses publicly available satellite observations and produces daily cloud-free images. Experimental results show that our system significantly outperforms baselines by 8dB in PSNR. We also demonstrate use cases of our system in digital agriculture, flood monitoring, and wildfire detection. We will release the processed dataset to facilitate future research.Preprint. Under review.

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Cloud Detection for Satellite Imagery Using Attention-Based U-Net Convolutional Neural Network

Cited by 57 publications

References 48 publications

Cloud and Cloud Shadow Segmentation for Remote Sensing Imagery Via Filtered Jaccard Loss Function and Parametric Augmentation

Cloud and Cloud Shadow Segmentation for Remote Sensing Imagery Via Filtered Jaccard Loss Function and Parametric Augmentation

Extrapolating shortwave geostationary satellite imagery of clouds into nighttime using longwave observations

Seeing Through Clouds in Satellite Images

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