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dc.creatorCassalho, Felício-
dc.creatorBeskow, Samuel-
dc.creatorMello, Carlos Rogério de-
dc.creatorMoura, Maíra Martim de-
dc.creatorOliveira, Leroi Floriano de-
dc.creatorAguiar, Marilton Sanchotene de-
dc.date.accessioned2020-04-01T20:06:53Z-
dc.date.available2020-04-01T20:06:53Z-
dc.date.issued2020-03-
dc.identifier.citationCASSALHO, F. et al. Artificial intelligence for identifying hydrologically homogeneous regions: a state‐of‐the‐art regional flood frequency analysis. Hydrological Processes, [S.l.], v. 33, n. 7, p. 1101-1116, Mar. 2019.pt_BR
dc.identifier.urihttps://onlinelibrary.wiley.com/doi/abs/10.1002/hyp.13388pt_BR
dc.identifier.urihttp://repositorio.ufla.br/jspui/handle/1/39653-
dc.description.abstractDue to the severity related to extreme flood events, recent efforts have focused on the development of reliable methods for design flood estimation. Historical streamflow series correspond to the most reliable information source for such estimation; however, they have temporal and spatial limitations that may be minimized by means of regional flood frequency analysis (RFFA). Several studies have emphasized that the identification of hydrologically homogeneous regions is the most important and challenging step in an RFFA. This study aims to identify state‐of‐the‐art clustering techniques (e.g., K‐means, partition around medoids, fuzzy C‐means, K‐harmonic means, and genetic K‐means) with potential to form hydrologically homogeneous regions for flood regionalization in Southern Brazil. The applicability of some probability density function, such as generalized extreme value, generalized logistic, generalized normal, and Pearson type 3, was evaluated based on the regions formed. Among all the 15 possible combinations of the aforementioned clustering techniques and the Euclidian, Mahalanobis, and Manhattan distance measures, the five best were selected. Several watersheds' physiographic and climatological attributes were chosen to derive multiple regression equations for all the combinations. The accuracy of the equations was quantified with respect to adjusted coefficient of determination, root mean square error, and Nash–Sutcliffe coefficient, whereas, a cross‐validation procedure was applied to check their reliability. It was concluded that reliable results were obtained when using robust clustering techniques based on fuzzy logic (e.g., K‐harmonic means), which have not been commonly used in RFFA. Furthermore, the probability density functions were capable of representing the regional annual maximum streamflows. Drainage area, main river length, and mean altitude of the watershed were the most recurrent attributes for modelling of mean annual maximum streamflow. Finally, an integration of all the five best combinations stands out as a robust, reliable, and simple tool for estimation of design floods.pt_BR
dc.languageen_USpt_BR
dc.publisherWileypt_BR
dc.rightsrestrictAccesspt_BR
dc.sourceHydrological Processespt_BR
dc.subjectCluster analysispt_BR
dc.subjectEvolutionary computationpt_BR
dc.subjectFuzzy logicpt_BR
dc.subjectHeterogeneity measurept_BR
dc.subjectIndex‐floodpt_BR
dc.subjectL‐momentspt_BR
dc.titleArtificial intelligence for identifying hydrologically homogeneous regions: a state‐of‐the‐art regional flood frequency analysispt_BR
dc.typeArtigopt_BR
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