Convective Cloud Detection and Tracking Using the New-Generation Geostationary Satellite Over South China

As a core element of weather and climate change research, convective clouds have complex physical structures and dynamic processes, and knowledge of their evolution is limited by remote sensing data along with detection and tracking algorithms. In this study, we construct convective cloud detection...

Full description

Saved in:
Bibliographic Details
Published in:IEEE transactions on geoscience and remote sensing 2023, Vol.61, p.1-12
Main Authors: Yang, Yikun, Zhao, Chuanfeng, Sun, Yue, Chi, Yulei, Fan, Hao
Format: Article
Language:English
Subjects:
Algorithms
Atmospheric modeling
Climate change
Climate change research
Clouds
Clustering algorithms
Convection
Convective cloud detection
convective cloud tracking
Convective clouds
Data models
Detection
Heuristic algorithms
Kalman filters
Learning algorithms
life cycle
Machine learning
Meteorology
Night
Optimization
Parallax
Radar
Radar tracking
Remote sensing
Spatial resolution
Spatiotemporal data
Spatiotemporal phenomena
Synchronous satellites
Tracking
Weather
Weather forecasting
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:As a core element of weather and climate change research, convective clouds have complex physical structures and dynamic processes, and knowledge of their evolution is limited by remote sensing data along with detection and tracking algorithms. In this study, we construct convective cloud detection and tracking algorithms for the Himawari-8 advanced Himawari-8 imager (AHI) data by combining machine learning models, area overlapping, and Kalman filter algorithms. First, we establish complicated and strict spatiotemporal data-matching conditions between the AHI and CloudSat Cloud Profile Radar (CPR) data, and a parallax correction model is developed to minimize the impact of parallax. To expand the sample volume of convective clouds, a region-growing algorithm is further used. Then, convective clouds during the day and night are detected based on the machine learning model which is trained through feature selection and hyper-parameter optimization. Finally, the automatic tracking of convective clouds, including those with relatively small scales or fast-moving speeds, is achieved by comprehensively using the area overlapping and Kalman filter algorithms. Validation results indicate that the algorithm developed can detect convective clouds of different scales with high accuracy, and the results show good continuity during day-to-night transitions. Moreover, the convective cloud detection algorithm can capture the convective clouds in advance compared with the traditional threshold algorithm. A case study of convective clouds demonstrates that the tracking algorithms we constructed can track convection at different scales. Overall, our study provides a new approach for convective cloud detection and tracking, which can contribute to a better understanding of weather and climate change.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2023.3298976