Intensity-Duration-Frequency Curves for Manicaragua city, Cuba

The Intensity-Duration-Frequency (IDF) curves are a way to visualize and represent extreme hydrometeorological rainfall events. In this article, an analysis of convective rainfall events recorded at the La Piedra Meteorological Station, Villa Clara, Cuba, was conducted. To develop IDF curves, the 20...

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Bibliographic Details
Published inEnfoque UTE : revista científica Vol. 15; no. 3; pp. 49 - 58
Main Authors López Ferraz, Roberto Luis, Castillo García, Carlos Lázaro, Domínguez Hurtado, Ismabel, Alejandro Solis, José, González Rodríguez, Lisdelys
Format Journal Article
LanguageEnglish
Portuguese
Published Universidad UTE 01.09.2024
Subjects
Agricultural Engineering
Automation & Control Systems
Computer Science, Information Systems
Engineering, Environmental
Engineering, Industrial
Engineering, Mechanical
Engineering, Petroleum
intensidad de la lluvia
precipitation
curves
rainfall intensity
umbral
Series de duración parcial
Partial duration series
threshold
precipitación
curvas
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Summary:The Intensity-Duration-Frequency (IDF) curves are a way to visualize and represent extreme hydrometeorological rainfall events. In this article, an analysis of convective rainfall events recorded at the La Piedra Meteorological Station, Villa Clara, Cuba, was conducted. To develop IDF curves, the 2006- 2019 time series was analyzed. A partial duration series was generated, including intervals from 20 minutes to 4320 minutes, subjected to an outlier detection process. The series was divided into two categories: one for durations ≤ 720 minutes and another for durations > 720 minutes. The resulting series underwent nonparametric tests to assess their independence, randomness, homogeneity, and seasonality. Subsequently, they were fitted to the Generalized Pareto probability distribution and to a parametric equation of the Montana model, and then the curves were plotted for return periods of 10, 50 and 100. The Montana model led to obtaining correlation coefficients greater than 0.90 compared to the other methods used, significantly improving the quality of the fit in both categories. This research provides information to understand and plan the management of intense climatic phenomena and adequate risk management in an area where such studies are lacking, facilitating access to crucial data essential in the design and execution of hydraulic engineering projects in the region.
ISSN:1390-9363
1390-6542
1390-6542
DOI:10.29019/enfoqueute.1046