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FLO-SR: Deep learning-based urban flood super-resolution model

Hyeonjin Choi, Hyuna Woo, Minyoung Kim, Hyungon Ryu, Jun‐Hak Lee, Seungsoo Lee, Seong Jin Noh

2025Journal of Hydrology11 citationsDOIOpen Access PDF

Abstract

Urban flooding, intensified by both climate change and urbanization, requires high-fidelity and computationally efficient modeling frameworks for effective risk assessment and mitigation. This study presents FLO-SR, a deep learning-based super-resolution (SR) model, to enhance the spatial resolution of urban flood simulations while significantly reducing computational costs. FLO-SR leverages a convolutional neural network (CNN) to convert low-resolution (LR) flood maps into high-resolution (HR) outputs. The model was validated using two distinct flood events: Hurricane Harvey in Houston, Texas (synthetic scenario using bicubic interpolation) and an urban flood event in Portland, Oregon (physics-based simulation scenario). FLO-SR was evaluated in terms of image similarity, flood depth, and inundation extent. FLO-SR achieved accuracy improvements in both cases at scale factors of 2, 4, and 8×, with average RMSE reductions of 56.2, 32.4, and 10.7 % in Houston and 24.5, 33.8, and 44.1 % in Portland. However, performance at the 8× scale was limited due to challenges in reconstructing fine-scale flood features and spatial discontinuities in LR inputs. To address this, future improvements should incorporate hydrodynamic constraints and enhance model generalization. Despite these limitations, FLO-SR combined with physics-based modeling achieved up to 63 % and 45.7 % runtime reductions when reconstructing 2 m from 4 m and 4 m from 8 m simulations, respectively, highlighting its potential for real-time urban flood forecasting.

Topics & Concepts

Flood mythEnvironmental scienceGeologyHydrology (agriculture)GeographyGeotechnical engineeringArchaeologyFlood Risk Assessment and ManagementAdvanced Image Processing TechniquesImage and Signal Denoising Methods