Precipitation frequency analysis from remotely sensed datasets: A focused review

Francesco Marra; Efthymios I. Nikolopoulos; Emmanouil N. Anagnostou; András Bárdossy; Efrat Morin

doi:10.1016/j.jhydrol.2019.04.081

Precipitation frequency analysis from remotely sensed datasets: A focused review

Francesco Marra^*, Efthymios I. Nikolopoulos, Emmanouil N. Anagnostou, András Bárdossy, Efrat Morin

^*Corresponding author for this work

Fredy & Nadine Herrmann Institute of Earth Sciences

Research output: Contribution to journal › Review article › peer-review

28 Scopus citations

Abstract

Information on extreme precipitation is essential to managing weather-related risks and designing hydraulic structures. Research attention to frequency analyses based on remotely sensed precipitation datasets, such as those obtained from weather radars and satellites, has been rapidly increasing owing to their potential to provide information for ungauged regions worldwide. Together with the ability to measure the areal scale directly, these analyses promise to overcome the sampling limitations of traditional methods based on rain gauges. This focused review of the literature depicts the state of the art after a decade of efforts, and identifies the crucial gaps in knowledge and methodology that currently hinder the quantitative use of remotely sensed datasets in water resources system design and operation. It concludes by highlighting a set of research directions promising immediate impact with regard to the separation of the sources of uncertainty currently affecting applications based on remotely sensed datasets, the development of statistical methods that can cope with the peculiar characteristics of these datasets, and the improvement of validation methods. Important gains in knowledge are expected from the explicit inclusion of the areal dimension in the analyses and from the fine-scale investigation of extreme precipitation climatology.

Original language	American English
Pages (from-to)	699-705
Number of pages	7
Journal	Journal of Hydrology
Volume	574
DOIs	https://doi.org/10.1016/j.jhydrol.2019.04.081
State	Published - Jul 2019

Bibliographical note

Funding Information:
This study was funded by the Israel Science Foundation [grant no. 1007/15 ], a National Science Foundation – Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut . The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript.

Funding Information:
This study was funded by the Israel Science Foundation [grant no. 1007/15], a National Science Foundation–Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut. The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript.

Publisher Copyright:
© 2019 Elsevier B.V.

Keywords

Extreme precipitation
Frequency analysis
Remote sensing
Review
Satellite
Weather radar

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10.1016/j.jhydrol.2019.04.081

Cite this

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title = "Precipitation frequency analysis from remotely sensed datasets: A focused review",

abstract = "Information on extreme precipitation is essential to managing weather-related risks and designing hydraulic structures. Research attention to frequency analyses based on remotely sensed precipitation datasets, such as those obtained from weather radars and satellites, has been rapidly increasing owing to their potential to provide information for ungauged regions worldwide. Together with the ability to measure the areal scale directly, these analyses promise to overcome the sampling limitations of traditional methods based on rain gauges. This focused review of the literature depicts the state of the art after a decade of efforts, and identifies the crucial gaps in knowledge and methodology that currently hinder the quantitative use of remotely sensed datasets in water resources system design and operation. It concludes by highlighting a set of research directions promising immediate impact with regard to the separation of the sources of uncertainty currently affecting applications based on remotely sensed datasets, the development of statistical methods that can cope with the peculiar characteristics of these datasets, and the improvement of validation methods. Important gains in knowledge are expected from the explicit inclusion of the areal dimension in the analyses and from the fine-scale investigation of extreme precipitation climatology.",

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author = "Francesco Marra and Nikolopoulos, {Efthymios I.} and Anagnostou, {Emmanouil N.} and Andr{\'a}s B{\'a}rdossy and Efrat Morin",

note = "Funding Information: This study was funded by the Israel Science Foundation [grant no. 1007/15 ], a National Science Foundation – Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut . The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript. Funding Information: This study was funded by the Israel Science Foundation [grant no. 1007/15], a National Science Foundation–Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut. The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript. Publisher Copyright: {\textcopyright} 2019 Elsevier B.V.",

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AU - Bárdossy, András

AU - Morin, Efrat

N1 - Funding Information: This study was funded by the Israel Science Foundation [grant no. 1007/15 ], a National Science Foundation – Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut . The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript. Funding Information: This study was funded by the Israel Science Foundation [grant no. 1007/15], a National Science Foundation–Binational Science Foundation grant [BSF 2016953], and the Eversource Energy Center at the University of Connecticut. The authors thank Editor-in-Chief Dr. Marco Borga for prompting the development of this focused review and, together with the anonymous reviewer, helping improving the quality of the manuscript. Publisher Copyright: © 2019 Elsevier B.V.

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N2 - Information on extreme precipitation is essential to managing weather-related risks and designing hydraulic structures. Research attention to frequency analyses based on remotely sensed precipitation datasets, such as those obtained from weather radars and satellites, has been rapidly increasing owing to their potential to provide information for ungauged regions worldwide. Together with the ability to measure the areal scale directly, these analyses promise to overcome the sampling limitations of traditional methods based on rain gauges. This focused review of the literature depicts the state of the art after a decade of efforts, and identifies the crucial gaps in knowledge and methodology that currently hinder the quantitative use of remotely sensed datasets in water resources system design and operation. It concludes by highlighting a set of research directions promising immediate impact with regard to the separation of the sources of uncertainty currently affecting applications based on remotely sensed datasets, the development of statistical methods that can cope with the peculiar characteristics of these datasets, and the improvement of validation methods. Important gains in knowledge are expected from the explicit inclusion of the areal dimension in the analyses and from the fine-scale investigation of extreme precipitation climatology.

AB - Information on extreme precipitation is essential to managing weather-related risks and designing hydraulic structures. Research attention to frequency analyses based on remotely sensed precipitation datasets, such as those obtained from weather radars and satellites, has been rapidly increasing owing to their potential to provide information for ungauged regions worldwide. Together with the ability to measure the areal scale directly, these analyses promise to overcome the sampling limitations of traditional methods based on rain gauges. This focused review of the literature depicts the state of the art after a decade of efforts, and identifies the crucial gaps in knowledge and methodology that currently hinder the quantitative use of remotely sensed datasets in water resources system design and operation. It concludes by highlighting a set of research directions promising immediate impact with regard to the separation of the sources of uncertainty currently affecting applications based on remotely sensed datasets, the development of statistical methods that can cope with the peculiar characteristics of these datasets, and the improvement of validation methods. Important gains in knowledge are expected from the explicit inclusion of the areal dimension in the analyses and from the fine-scale investigation of extreme precipitation climatology.

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Precipitation frequency analysis from remotely sensed datasets: A focused review

Abstract

Bibliographical note

Keywords

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