Abstract
Precipitation, especially convective precipitation, is highly associated with hydrological disasters (e.g., floods and drought) that have negative impacts on agricultural productivity, society, and the environment. To mitigate these negative impacts, it is crucial to monitor the precipitation status in real time. The new Advanced Baseline Imager (ABI) onboard the GOES-16 satellite provides such a precipitation product in higher spatiotemporal and spectral resolutions, especially during the daytime. This research proposes a deep neural network (DNN) method to classify rainy and non-rainy clouds based on the brightness temperature differences (BTDs) and reflectances (Ref) derived from ABI. Convective and stratiform rain clouds are also separated using similar spectral parameters expressing the characteristics of cloud properties. The precipitation events used for training and validation are obtained from the IMERG V05B data, covering the southeastern coast of the U.S. during the 2018 rainy season. The performance of the proposed method is compared with traditional machine learning methods, including support vector machines (SVMs) and random forest (RF). For rainy area detection, the DNN method outperformed the other methods, with a critical success index (CSI) of 0.71 and a probability of detection (POD) of 0.86. For convective precipitation delineation, the DNN models also show a better performance, with a CSI of 0.58 and POD of 0.72. This automatic cloud classification system could be deployed for extreme rainfall event detection, real-time forecasting, and decision-making support in rainfall-related disasters.
Highlights
Precipitation is one of the most significant contributing factors to destructive natural disasters globally, including hurricanes, floods, and droughts
Infrared (IR) data are more widely used in authoritative precipitation products including the Tropical Rainfall Measuring Mission (TRMM) 3B42 [11], Integrated Multi-Satellite Retrievals for Global Precipitation Measurement (IMERG) [12], and Climate Prediction Center Morphing Technique (CMORPH) global precipitation analyses [13]
Given the advantages of optical sensor data, this paper focuses on rainy cloud detection and convective precipitation delineation using images of IR and the visible spectrum
Summary
Precipitation is one of the most significant contributing factors to destructive natural disasters globally, including hurricanes, floods, and droughts. Convective precipitation with abnormal activities may lead to severe urban floods [1], landslides [2], and flash floods [3], which cause devastating short-term and long-term impacts on people, economies, infrastructure, and ecosystems. To mitigate these negative impacts, precipitation detection and convective precipitation detection are essential in extreme precipitation monitoring, forecasting, and early warning systems. The increasing availability of high spatiotemporal resolution datasets is contributing to the real-time detection and monitoring of precipitation events in a limited fashion for various domains, including environmental science [4], climate change [5], the economy [6], and society [7]. Given the advantages of optical sensor data, this paper focuses on rainy cloud detection and convective precipitation delineation using images of IR and the visible spectrum
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