A New Event‐Based Error Decomposition Scheme for Satellite Precipitation Products

Li, Runze; Guilloteau, Clement; Kirstetter, Pierre‐Emmanuel; Foufoula‐Georgiou, Efi

doi:10.1029/2023gl105343

Geophysical Research Letters

2023

DOI: 10.1029/2023gl105343

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A New Event‐Based Error Decomposition Scheme for Satellite Precipitation Products

Runze Li,

Clement Guilloteau,

Pierre‐Emmanuel Kirstetter

et al.

Abstract: Understanding the nature and origin of errors in satellite precipitation products is important for applications and product improvement. Here we propose a new error decomposition scheme incorporating precipitation event (continuous rainy periods) information to characterize satellite errors. Under this framework, the errors are attributed to the inaccuracies in event occurrence, timing (event start/end time), and intensity. The Integrated MultisatellitE Retrieval for Global Precipitation Measurement (IMERG) is… Show more

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2024

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Warm-Season Microwave Integrated Retrieval System Precipitation Improvement Using Machine Learning Methods

Liu,

Grassotti,

Liu

2024

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

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This study compares the performance of five selected machine learning models regarding precipitation climatology during the warm season in 2022 and 2023 over the Continental U.S. Input features included retrieved products from the Microwave Integrated Retrieval System (MiRS) based on NOAA-20 ATMS data. The radar-based instantaneous Multi-Radar Multi-Sensor System precipitation was used for model training and validation. Among the models, three used a U-Net architecture and two used a Deep Neural Network (DNN) architecture. The U-Net models all significantly outperformed DNN models for the evaluated metrics. While the DNN architecture can only learn from local inputs, the U-Net also has the capability to learn from neighborhood spatial patterns. As such, the DNN overcorrected the precipitation amounts that MiRS had overestimated, leading to net underestimation, but also failed to improve the overall performance relative to the original MiRS estimates. The U-Net not only corrected MiRS overestimation in the central U.S., but also improved the MiRS dry bias over the Southeast.Of the five experiments, that which used the MiRS retrieved column-integrated hydrometeors of graupel water path, rain water path, cloud liquid water, total precipitable water and geolocation information demonstrated the best performance, improving the MiRS spatial correlation coefficient from 0.75 to 0.89 and reducing the mean bias percentage from 11.95% to -6.33% for 2022 accumulated precipitation. This suggests that applying an appropriate architecture and input features provides an opportunity to determine more accurate physical and statistical relationships which can include spatial and regional dependence, leading to improved microwave-based precipitation estimates.

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Warm-Season Microwave Integrated Retrieval System Precipitation Improvement Using Machine Learning Methods

Liu,

Grassotti,

Liu

2024

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

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Remote Sensing-Based Analysis of Precipitation Events: Spatiotemporal Characterization across China

Zhu,

Peng,

et al. 2024

Water

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Precipitation occurs in individual events, but the event characteristics of precipitation are often neglected. This work seeks to identify the precipitation events on both spatial and temporal scales, explore the event characteristics of precipitation, and reveal the relationships between the different characteristics of precipitation events. To do this, we combined the Forward-in-Time (FiT) algorithm with the gridded hourly precipitation product to detect precipitation events in time and space over China. The identified precipitation events were analyzed to determine their characteristics. The results indicate that precipitation events can be detected and identified in time and space scales based on the FiT algorithm and the gridded hourly precipitation product. The precipitation total, duration, and intensity of these events decrease gradually from the southern (eastern) coastal regions to northern (western) inland areas of China. The event precipitation totals are strongly correlated with event duration and event maximum intensity; the totals are more strongly correlated with event maximum intensity and event intensity in the regions with lower precipitation than the regions with higher precipitation. More than 90% of precipitation events are shorter than 6 h, and events with long duration normally occur in temperate monsoon (TM) and subtropical/tropical monsoon (ST) climate zones. Heavy precipitation events with a duration longer than 7 h generally occur more than seven times per year in TM and ST climate zones. Our results suggest that precipitation analyses should sufficiently consider the characteristics of events across different regions.

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A New Event‐Based Error Decomposition Scheme for Satellite Precipitation Products

Cited by 2 publications

References 47 publications

Warm-Season Microwave Integrated Retrieval System Precipitation Improvement Using Machine Learning Methods

Warm-Season Microwave Integrated Retrieval System Precipitation Improvement Using Machine Learning Methods

Remote Sensing-Based Analysis of Precipitation Events: Spatiotemporal Characterization across China

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