Effective Cloud Detection and Segmentation using a Gradient-Based Algorithm for Satellite Imagery; Application to improve PERSIANN-CCS

@article{Hayatbini2018EffectiveCD,
  title={Effective Cloud Detection and Segmentation using a Gradient-Based Algorithm for Satellite Imagery; Application to improve PERSIANN-CCS},
  author={Negin Hayatbini and Kuo-lin Hsu and Soroosh Sorooshian and Yunji Zhang and Fuqing Zhang},
  journal={ArXiv},
  year={2018},
  volume={abs/1809.10801}
}
The effective identification of clouds and monitoring of their evolution are important toward more accurate quantitative precipitation estimation and forecast. In this study, a new gradient-based cloud-image segmentation algorithm is developed using image processing techniques. This method integrates morphological image gradient magnitudes to separate cloud systems and patches boundaries. A varying scale kernel is implemented to reduce the sensitivity of image segmentation to noise and to… 
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12 Citations

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The hybrid approach using machine learning, physical parameter retrieval, and ground-based validation is recommended for model improvement.

Cloud detection methodologies: variants and development—a review

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PERSIANN Dynamic Infrared–Rain Rate Model (PDIR) for High-Resolution, Real-Time Satellite Precipitation Estimation

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Can Remote Sensing Technologies Capture the Extreme Precipitation Event and Its Cascading Hydrological Response? A Case Study of Hurricane Harvey Using EF5 Modeling Framework

The results indicate that remote sensing technologies can accurately detect and estimate the unprecedented precipitation event with their near-real-time products, and all precipitation products produced good hydrological simulations.

Identification of tropical cyclones via deep convolutional network based on satellite cloud images

This paper presents a methodology which identifies TC fingerprint via Deep Convolutional Neural Network techniques based on SCIs of more than 200 TCs over the Northwest Pacific basin and shows that all the fingerprint features are focused on clouds during the testing process.

Identification of tropical cyclones via deep convolutional neural network based on satellite cloud images

This paper presents a methodology which identifies TC fingerprint via Deep Convolutional Neural Network techniques based on SCIs of more than 200 TCs over the Northwest Pacific basin, which shows that all the fingerprint features are focused on clouds during the testing process.

Conditional Generative Adversarial Networks (cGANs) for Near Real-Time Precipitation Estimation from Multispectral GOES-16 Satellite Imageries - PERSIANN-cGAN

This framework is proposed as an augmentation for PERSIANN-CCS (Precipitation Estimation from Remotely Sensed Information using Artificial Neural Network- Cloud Classification System) algorithm for estimating global precipitation.

Correlation Structures between Satellite All-Sky Infrared Brightness Temperatures and the Atmospheric State at Storm Scales

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Increases in precipitation rates and volumes from tropical cyclones (TCs) caused by anthropogenic warming are predicted by climate modeling studies and have been identified in several high intensity

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