A Lower-Bounded Extreme Value Distribution for Flood Frequency Analysis with Applications

Fatimah E. Almuhayfith; Maher Kachour; Amira F. Daghestani; Zahid Ur Rehman; Tassaddaq Hussain; Hassan S. Bakouch

doi:10.3390/math13213378

A Lower-Bounded Extreme Value Distribution for Flood Frequency Analysis with Applications

Fatimah E. Almuhayfith^*
, Maher Kachour
, Amira F. Daghestani
, Zahid Ur Rehman
, Tassaddaq Hussain
, Hassan S. Bakouch^*

^*Corresponding author for this work

King Faisal University
Gulf University for Science and Technology
Mirpur University of Science and Technology
Qassim University

Research output: Contribution to journal › Article › peer-review

Abstract

This paper proposes the lower-bounded Fréchet–log-logistic distribution (LFLD), a probability model designed for robust flood frequency analysis (FFA). The LFLD addresses key limitations of traditional distributions (e.g., generalized extreme value (GEV) and log-Pearson Type III (LP3)) by combining bounded support ((Formula presented.)) to reflect physical flood thresholds, flexible tail behavior via Fréchet–log-logistic fusion for extreme-value accuracy, and maximum entropy characterization, ensuring optimal parameter estimation. Thus, we obtain the LFLD’s main statistical properties (PDF, CDF, and hazard rate), prove its asymptotic convergence to Fréchet distributions, and validate its superiority through simulation studies showing MLE consistency (bias < 0.02 and mean squared error < 0.0004 for (Formula presented.)) and empirical flood data tests (52- and 98-year AMS series), where the LFLD outperforms 10 competitors (AIC reductions of 15–40%; Vuong test p < 0.01). The LFLD’s closed-form quantile function enables efficient return period estimation, critical for infrastructure planning. Results demonstrate its applicability to heavy-tailed, bounded hydrological data, offering a 20–30% improvement in flood magnitude prediction over LP3/GEV models.

Original language	English
Article number	3378
Pages (from-to)	1-24
Number of pages	24
Journal	Mathematics
Volume	13
Issue number	21
DOIs	https://doi.org/10.3390/math13213378
State	Published - Nov 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure
SDG 11 Sustainable Cities and Communities

Keywords

flood frequency analysis
bounded distributions
Fréchet distribution
log-logistic model
entropy
extreme value theory
return period estimation

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10.3390/math13213378

Cite this

@article{ca4a014fdb9043938495297d6d345697,

title = "A Lower-Bounded Extreme Value Distribution for Flood Frequency Analysis with Applications",

abstract = "This paper proposes the lower-bounded Fr{\'e}chet–log-logistic distribution (LFLD), a probability model designed for robust flood frequency analysis (FFA). The LFLD addresses key limitations of traditional distributions (e.g., generalized extreme value (GEV) and log-Pearson Type III (LP3)) by combining bounded support ((Formula presented.)) to reflect physical flood thresholds, flexible tail behavior via Fr{\'e}chet–log-logistic fusion for extreme-value accuracy, and maximum entropy characterization, ensuring optimal parameter estimation. Thus, we obtain the LFLD{\textquoteright}s main statistical properties (PDF, CDF, and hazard rate), prove its asymptotic convergence to Fr{\'e}chet distributions, and validate its superiority through simulation studies showing MLE consistency (bias < 0.02 and mean squared error < 0.0004 for (Formula presented.)) and empirical flood data tests (52- and 98-year AMS series), where the LFLD outperforms 10 competitors (AIC reductions of 15–40\%; Vuong test p < 0.01). The LFLD{\textquoteright}s closed-form quantile function enables efficient return period estimation, critical for infrastructure planning. Results demonstrate its applicability to heavy-tailed, bounded hydrological data, offering a 20–30\% improvement in flood magnitude prediction over LP3/GEV models.",

keywords = "flood frequency analysis, bounded distributions, Fr{\'e}chet distribution, log-logistic model, entropy, extreme value theory, return period estimation",

author = "Almuhayfith, \{Fatimah E.\} and Maher Kachour and Daghestani, \{Amira F.\} and Rehman, \{Zahid Ur\} and Tassaddaq Hussain and Bakouch, \{Hassan S.\}",

note = "Publisher Copyright: {\textcopyright} 2025 by the authors.",

year = "2025",

month = nov,

doi = "10.3390/math13213378",

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T1 - A Lower-Bounded Extreme Value Distribution for Flood Frequency Analysis with Applications

AU - Almuhayfith, Fatimah E.

AU - Kachour, Maher

AU - Daghestani, Amira F.

AU - Rehman, Zahid Ur

AU - Hussain, Tassaddaq

AU - Bakouch, Hassan S.

PY - 2025/11

Y1 - 2025/11

N2 - This paper proposes the lower-bounded Fréchet–log-logistic distribution (LFLD), a probability model designed for robust flood frequency analysis (FFA). The LFLD addresses key limitations of traditional distributions (e.g., generalized extreme value (GEV) and log-Pearson Type III (LP3)) by combining bounded support ((Formula presented.)) to reflect physical flood thresholds, flexible tail behavior via Fréchet–log-logistic fusion for extreme-value accuracy, and maximum entropy characterization, ensuring optimal parameter estimation. Thus, we obtain the LFLD’s main statistical properties (PDF, CDF, and hazard rate), prove its asymptotic convergence to Fréchet distributions, and validate its superiority through simulation studies showing MLE consistency (bias < 0.02 and mean squared error < 0.0004 for (Formula presented.)) and empirical flood data tests (52- and 98-year AMS series), where the LFLD outperforms 10 competitors (AIC reductions of 15–40%; Vuong test p < 0.01). The LFLD’s closed-form quantile function enables efficient return period estimation, critical for infrastructure planning. Results demonstrate its applicability to heavy-tailed, bounded hydrological data, offering a 20–30% improvement in flood magnitude prediction over LP3/GEV models.

AB - This paper proposes the lower-bounded Fréchet–log-logistic distribution (LFLD), a probability model designed for robust flood frequency analysis (FFA). The LFLD addresses key limitations of traditional distributions (e.g., generalized extreme value (GEV) and log-Pearson Type III (LP3)) by combining bounded support ((Formula presented.)) to reflect physical flood thresholds, flexible tail behavior via Fréchet–log-logistic fusion for extreme-value accuracy, and maximum entropy characterization, ensuring optimal parameter estimation. Thus, we obtain the LFLD’s main statistical properties (PDF, CDF, and hazard rate), prove its asymptotic convergence to Fréchet distributions, and validate its superiority through simulation studies showing MLE consistency (bias < 0.02 and mean squared error < 0.0004 for (Formula presented.)) and empirical flood data tests (52- and 98-year AMS series), where the LFLD outperforms 10 competitors (AIC reductions of 15–40%; Vuong test p < 0.01). The LFLD’s closed-form quantile function enables efficient return period estimation, critical for infrastructure planning. Results demonstrate its applicability to heavy-tailed, bounded hydrological data, offering a 20–30% improvement in flood magnitude prediction over LP3/GEV models.

KW - flood frequency analysis

KW - bounded distributions

KW - Fréchet distribution

KW - log-logistic model

KW - entropy

KW - extreme value theory

KW - return period estimation

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DO - 10.3390/math13213378

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EP - 24

JO - Mathematics

JF - Mathematics

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ER -

A Lower-Bounded Extreme Value Distribution for Flood Frequency Analysis with Applications

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