Spatiotemporal Variability of Current and Future Sub‐Daily Rainfall in Japan Using State‐Of‐The‐Art High‐Quality Data Sets

Zhao, Wenpeng; Abhishek, Abhishek; Takhellambam, Bijoychandra S.; Zhang, Jian-Tao; Zhao, Yaohua; Kinouchi, Tsuyoshi

doi:10.1029/2022wr034305

Cited by 9 publications

(8 citation statements)

References 94 publications

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“…They provide the mathematical link between precipitation intensities (I), durations (D), areas (A), and frequency of occurrence (F). They are useful tools for engineers and hydrologists in hydrological design (see Bertini et al., 2020, for example), quantification of areal rainfall hazard (Mélèse et al., 2019; Overeem et al., 2010; Panthou et al., 2014; Zhao et al., 2023), storm characterization (Blanchet & Mélèse, 2020; Ceresetti et al., 2012; Ramos et al., 2005), and development of early warning systems (Panziera et al., 2016). IDAF models extend the well‐known Intensity Duration Frequency curves (IDF) by incorporating the spatial extent of precipitation (i.e., the area).…”

Section: Introductionmentioning

confidence: 99%

“…A rare application of GPD for threshold excesses is found in Zhao et al. (2023) for IDAF curve modeling. A major drawback of such approaches is the inefficient use of the data since only one value is retained in a block (usually the maximum in a year) or the excesses of a threshold (a tiny fraction of the data), and all the other data in the block is discarded.…”

Section: Introductionmentioning

confidence: 99%

“…This can result in significant uncertainty in estimation, especially in cases where the length of the data series is not sufficiently long. The problem of short record length is more apparent with radar and radar reanalysis products, which are usually used in IDAF curve modeling (Blanchet & Mélèse, 2020; Mélèse et al., 2019; Overeem et al., 2010; Zhao et al., 2023), due to the required spatial information they provide.…”

Section: Introductionmentioning

confidence: 99%

“…To elaborate more, all the authors used only extreme data in the form of block maxima and, as the distribution, the generalized extreme value (GEV) distribution (Ceresetti et al, 2012;Overeem et al, 2010;Panthou et al, 2014) or its special case, the Gumbel distribution (Bertini et al, 2020;Blanchet & Mélèse, 2020;Mélèse et al, 2019;Nhat et al, 2007), or log-normal distribution (De Michele et al, 2011). A rare application of GPD for threshold excesses is found in Zhao et al (2023) for IDAF curve modeling. A major drawback of such approaches is the inefficient use of the data since only one value is retained in a block (usually the maximum in a year) or the excesses of a threshold (a tiny fraction of the data), and all the other data in the block is discarded.…”

mentioning

confidence: 99%

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Estimation of Intensity‐Duration‐Area‐Frequency Relationships Based on the Full Range of Non‐Zero Precipitation From Radar‐Reanalysis Data

Haruna,

Blanchet,

Favre

2024

Water Resources Research

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Intensity‐Duration‐Area‐Frequency (IDAF) models provide the mathematical link between precipitation intensities (I), durations (D), areas (A), and frequency of occurrence (F). They play a critical role in hydrological design, areal rainfall hazard quantification, storm characterization, and early warning system development. IDAF models extend the conventional Intensity‐Duration‐Frequency models by accounting for the spatial extent of precipitation (i.e., the area). In this study, we develop IDAF models using the entire non‐zero precipitation intensities, not only the extremes. We use the extended generalized Pareto distribution (EGPD) to model the precipitation intensities. To build the IDAF models, we adopt a data‐driven approach that allows the linkage of EGPD parameters with duration and area, based on empirically determined parametric relationships. The inference of model parameters is done using a global maximum likelihood estimation, and uncertainties are assessed by the bootstrap method. The study area is Switzerland, a topographically complex region of 42,000 km2 with regional precipitation variability and clear seasonality. The study utilizes 17 years of data from CombiPrecip, a radar‐reanalysis product developed by geostatistically merging radar and rain gauge data in an operational setting. We build the IDAF models for the spatiotemporal range of 1–72 hr and 1 to 1,089 km2 at each pixel in the study area. To the best of our knowledge, our study is the first attempt to use the EGPD in IDAF curve modeling. It discusses the use and limitations of CombiPrecip in extreme value analysis and highlights the challenges of modeling areal precipitation in a complex topographical environment.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Estimation of Intensity‐Duration‐Area‐Frequency Relationships Based on the Full Range of Non‐Zero Precipitation From Radar‐Reanalysis Data

Haruna,

Blanchet,

Favre

2024

Water Resources Research

View full text Add to dashboard Cite

show abstract

“…They provide the mathematical link between precipitation intensities (I), durations (D), areas (A), and frequency of occurrence (F). They are useful tools for engineers and hydrologists in hydrological design (see Bertini et al, 2020, for example), quantification of areal rainfall hazard (Overeem et al, 2010;Panthou et al, 2014;Mélèse et al, 2019;Zhao et al, 2023), storm characterization (Ramos et al, 2005;Ceresetti et al, 2012;Blanchet & Mélèse, 2020), and development of early warning systems (Panziera et al, 2016). IDAF models extend the well-known Intensity Duration Frequency curves (IDF) by incorporating the spatial extent of precipitation (i.e., the area).…”

Section: Introductionmentioning

confidence: 99%

Modeling Areal Precipitation Hazard: A Data-driven Approach to Model Intensity-Duration-Area-Frequency Relationships using the Full Range of Non-Zero Precipitation in Switzerland

Haruna

Blanchet

Favre

2023

Preprint

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Intensity-Duration-Area-Frequency (IDAF) models provide the mathematical link between precipitation intensities (I), durations (D), areas (A), and frequency of occurrence (F). They play a critical role in hydrological design, areal rainfall hazard quantification, storm characterization, and early warning system development. IDAF models extend the conventional Intensity-Duration-Frequency (IDF) models by accounting for the spatial extent of precipitation({\it i.e.}, the area). In this study, we develop IDAF models using the entire non-zero precipitation intensities, not only the extremes. We use the extended generalized Pareto distribution (EGPD) to model the precipitation intensities. To build the IDAF models, we adopt a data-driven approach that allows the linkage of EGPD parameters with duration and area, based on empirically determined parametric relationships. The inference of model parameters is done using a global maximum likelihood estimation, and uncertainties are assessed by the bootstrap method. The study area is Switzerland, a topographically complex region of 42,000 km$^2$ with regional precipitation variability and clear seasonality. The study utilizes 17-years of data from \texttt{CombiPrecip}, a radar-reanalysis product developed by geostatistically merging radar and rain gauge data in an operational setting. We build the IDAF models for the spatiotemporal range of 1 to 72 hours and 1 to 1,089 km$^2$ at each pixel in the study area. To the best of our knowledge, our study is the first attempt to use the EGPD in IDAF curve modeling. It discusses the use and limitations of \texttt{CombiPrecip} in extreme value analysis and highlights the challenges of modeling areal precipitation in a complex topographical environment.

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Artificial neural network-empowered projected future rainfall intensity-duration-frequency curves under changing climate

Takhellambam,

Srivastava,

Lamba

et al. 2024

Atmospheric Research

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Spatiotemporal Variability of Current and Future Sub‐Daily Rainfall in Japan Using State‐Of‐The‐Art High‐Quality Data Sets

Cited by 9 publications

References 94 publications

Estimation of Intensity‐Duration‐Area‐Frequency Relationships Based on the Full Range of Non‐Zero Precipitation From Radar‐Reanalysis Data

Estimation of Intensity‐Duration‐Area‐Frequency Relationships Based on the Full Range of Non‐Zero Precipitation From Radar‐Reanalysis Data

Modeling Areal Precipitation Hazard: A Data-driven Approach to Model Intensity-Duration-Area-Frequency Relationships using the Full Range of Non-Zero Precipitation in Switzerland

Artificial neural network-empowered projected future rainfall intensity-duration-frequency curves under changing climate

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