Iran-Water Resources Research

Iran-Water Resources Research

Estimating Flood Economic Damages through Integrated Hydro-Meteorological Modeling and Hydraulic Simulation: A Novel Approach for Flood Management and Damage Reduction (Case Study: Poldokhtar Basin)

Document Type : Original Article

Authors
Sakineh Koohi 1
Asghar Azizian 2
Saeid Najafi 3
1 Phd in Water Resources Engineering
2 Assistant Professor in Water Engineering Dept./ Imam Khomeini International University
3 Ministry of Energy, Water Research Institute (WRI)
10.22034/iwrr.2025.512419.2840
Abstract
In recent years, the growing frequency of flood events and their associated damages has underscored the critical need to enhance flood risk management strategies, particularly in identifying flood-prone areas and assessing the extent of damage they incur. Recognizing the pivotal role of depth-damage functions in flood damage evaluation, this study focuses on Poldokhtar basin as a case study. It develops a regional model for estimating flood damage in residential areas while evaluating the potential of utilizing outputs from the WRF numerical weather model combined with HEC-HMS and HEC-RAS models to estimate hydrological, hydraulic, and damage components of flood. The study employs the WRF model for precipitation prediction, the HEC-HMS hydrological model for flood simulation, and the two-dimensional HEC-RAS hydraulic model for flood inundation simulation. The findings demonstrated that the WRF model combined with HEC-HMS and HEC-RAS models performs effectively in hydrological and hydraulic modeling, with minimal errors: approximately 1.47% in estimating peak flood discharge, 2.98% in simulating flood depth, and 1.93% in WSE. Additionally, the developed damage model exhibited strong accuracy, with a relative error of less than 10% in estimating flood damages in residential areas. The study also highlighted that improving spatial accuracy in calculating building areas and applying reconstruction/renovation cost coefficients for shallow floods resulted in more precise damage estimates. Integrating these models and methodologies into an online platform could serve as a comprehensive and practical forecasting system, offering significant value to researchers and policymakers at the national level. Such a system would play a crucial role in mitigating and managing flood-related damages.
 
Keywords
Flood Damage, Integrated Meteorological-Hydrological Modeling, Depth-Damage Functions, Reconstruction/Renovation Cost Factor, Economic Flood Analysis

Subjects

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  • Receive Date 14 March 2025
  • Revise Date 06 May 2025
  • Accept Date 11 June 2025