Abstract
This study proposed a real-time flood extent prediction method to shorten the time it takes from the flood occurrence to an alert issuance. This method uses logistic regression to generate a flood probability discriminant for each grid constituting the study area, and then predicts the flood extent with the amount of runoff caused by rainfall. In order to generate the flood probability discriminant for each grid, a two-dimensional (2D) flood inundation model was verified by applying the Typhoon Chaba, which caused great damage to the study area in 2016. Then, 100 probability rainfall scenarios were created by combining the return period, duration, and time distribution using past observation rainfall data, and rainfall-runoff–inundation relation databases were built for each scenario by applying hydrodynamic and hydrological models. A flood probability discriminant based on logistic regression was generated for each grid by using whether the grid was flooded (1 or 0) for the runoff amount in the database. When the runoff amount is input to the generated discriminant, the flood probability on the target grid is calculated by the coefficients, so that the flood extent is quickly predicted. The proposed method predicted the flood extent in a few seconds in both cases and showed high accuracy with 83.6~98.4% and 74.4~99.1%, respectively, in the application of scenario rainfall and actual rainfall.
Highlights
Floods have been frequently occurring in Korea and around the world due to climate change
The proposed method creates a unique regression equation that considers regional The real-time flood extent prediction method proposed in this study has the strength characteristics using a database built with scenario rainfall and hydraulic and hydrological of reducing the time required for 2D flood analysis while maintaining accuracy by models
This study proposes a real-time flood extent prediction method using logistic regression
Summary
Floods have been frequently occurring in Korea and around the world due to climate change. In Korea, hydraulic structures are designed with 80 to 200 years of floods depending on the size of the rivers to prevent floods. 132 mm/h in 2016 was much higher than the 200-year frequency rainfall of 86.8 mm/h in the Taehwa River basin, which is the study area. The goals for disaster prevention capability of rivers and hydraulic structures set to reduce flood damage are designed to be lower. Since rainfalls of strong intensity are occurring locally and suddenly, it is necessary to establish a comprehensive disaster response system for reducing and predicting flood damages
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
