Sudden flooding has been on the rise in the watersheds that have undergone significant urbanization, and this is attributable to climate change. This trend presents the potential of tremendous property damage and losses of lives, and diverse methods have been applied to address the issue with greate...
Sudden flooding has been on the rise in the watersheds that have undergone significant urbanization, and this is attributable to climate change. This trend presents the potential of tremendous property damage and losses of lives, and diverse methods have been applied to address the issue with greater efficiency. Unlike the traditional numerical analysis models and statistical analysis methods, flood analysis using machine learning is a data-based analysis that can present results in a short period of time through prior learning. Flood analysis based on machine learning involves the use of a wide range of simulation-based and observational data, and thus may be viewed as a type of data-based analysis. Accordingly, it is important to apply rational machine learning techniques along with data that are appropriate in terms of quality and quantity, and this technique may be actively applied to analyze and respond to unforeseen hydrological events and disasters. In this study, a machine learning technique with the use of one- and two-dimensional numerical analysis models, diverse hydrological observation data, and deep learning was applied.
As for the water disaster analysis and prediction, an analysis of the upper and lower streams of the Paldang dam and a flood analysis of a single urban drainage basin were carried out. With respect to an inflow of dams with a return period of 200 years or more, a flood map prediction for rising water levels of the Han-river was made with the application of the random-forest regression technique, and this is considered to be an efficient method to determine in real time the flooding pattern for the excessive dam inflow that can be expected. Using the range of flooding according to the amount of dam inflow under the probable maximum flood (PMF) condition, the utility of the flooding range prediction technique was proposed. The order of priority of the flood response to be made by each district of Seoul to counter the economic damage resulting from flooded buildings and casualties, and the level of importance of each factor affecting flood damage was estimated using the random forest technique. The proposed method can be used to select the districts in which flood response and restoration must be performed first in the event that a large-scale flood with a recurrence interval of 200 years or more occurs in the watershed of a metropolitan city.
The flood analysis of urban drainage basin units was conducted on Samseong drainage basin, and a LSTM (Long Short Term Memory) neural network model capable of predicting the total amount of overflow in real time according to the occurrence of rainfall events was trained. A comparison with the verified one-dimensional urban runoff analysis model showed that the LSTM neural network model could even accurately model the peak overflow. Using the predicted total overflow, the flooding range and flood risk map were predicted. When predicting the flooding range, the range was predicted based on the flooding depth using the logistic regression technique, and while it failed to produce a high area fitness for a relatively high flooding depth, it was deemed to be a highly appropriate method for predicting the overall flooding range according to the rainfall intensity. For the analysis of the flood risk map, the formula for calculating the flood risk level presented in the Department for Environment, Food & Rural Affairs, Environment Agency (DEFRA)’s Flood Risks to People report was used, and the flood risk level was determined in grid units using the flooding depth and flow rate information obtained from the two-dimensional flood analysis. A flood risk map was generated by taking into consideration both scenarios in which the debris factor associated with water disasters was and was not considered, and predictions were made through random-forest classifications. The results of the prediction and analysis showed that a relatively high flood risk level was found in residential areas with many alleys when the debris factor was taken into account. The prediction results using the random forest were compared with the results of using the flood risk calculation formula, and a high degree of agreement was found. Thus, it was judged that suggested methodology could be used as providing the useful data for performing flood control of each urban drainage basin at a later time.
Through flood prediction and analysis using diverse machine learning, it is possible to determine the danger zones in real-time in the event of a water disaster. The proposed methodology can be said to have high reliability and accuracy, as it uses a database built based on observational data and the results of applying verified numerical analysis models. Its practicality was also demonstrated by presenting the method of utilization with respect to the prediction and analysis results, and it is expected that the prediction model will help speed up the processes of the urban watershed flood control system if it is improved with more basic data. The aim of this study was to demonstrate the diverse uses of various observational data and numerical analysis models in connection with machine learning techniques and that they are accurate enough to be actively applied in practice to defend against flooding.
Sudden flooding has been on the rise in the watersheds that have undergone significant urbanization, and this is attributable to climate change. This trend presents the potential of tremendous property damage and losses of lives, and diverse methods have been applied to address the issue with greater efficiency. Unlike the traditional numerical analysis models and statistical analysis methods, flood analysis using machine learning is a data-based analysis that can present results in a short period of time through prior learning. Flood analysis based on machine learning involves the use of a wide range of simulation-based and observational data, and thus may be viewed as a type of data-based analysis. Accordingly, it is important to apply rational machine learning techniques along with data that are appropriate in terms of quality and quantity, and this technique may be actively applied to analyze and respond to unforeseen hydrological events and disasters. In this study, a machine learning technique with the use of one- and two-dimensional numerical analysis models, diverse hydrological observation data, and deep learning was applied.
As for the water disaster analysis and prediction, an analysis of the upper and lower streams of the Paldang dam and a flood analysis of a single urban drainage basin were carried out. With respect to an inflow of dams with a return period of 200 years or more, a flood map prediction for rising water levels of the Han-river was made with the application of the random-forest regression technique, and this is considered to be an efficient method to determine in real time the flooding pattern for the excessive dam inflow that can be expected. Using the range of flooding according to the amount of dam inflow under the probable maximum flood (PMF) condition, the utility of the flooding range prediction technique was proposed. The order of priority of the flood response to be made by each district of Seoul to counter the economic damage resulting from flooded buildings and casualties, and the level of importance of each factor affecting flood damage was estimated using the random forest technique. The proposed method can be used to select the districts in which flood response and restoration must be performed first in the event that a large-scale flood with a recurrence interval of 200 years or more occurs in the watershed of a metropolitan city.
The flood analysis of urban drainage basin units was conducted on Samseong drainage basin, and a LSTM (Long Short Term Memory) neural network model capable of predicting the total amount of overflow in real time according to the occurrence of rainfall events was trained. A comparison with the verified one-dimensional urban runoff analysis model showed that the LSTM neural network model could even accurately model the peak overflow. Using the predicted total overflow, the flooding range and flood risk map were predicted. When predicting the flooding range, the range was predicted based on the flooding depth using the logistic regression technique, and while it failed to produce a high area fitness for a relatively high flooding depth, it was deemed to be a highly appropriate method for predicting the overall flooding range according to the rainfall intensity. For the analysis of the flood risk map, the formula for calculating the flood risk level presented in the Department for Environment, Food & Rural Affairs, Environment Agency (DEFRA)’s Flood Risks to People report was used, and the flood risk level was determined in grid units using the flooding depth and flow rate information obtained from the two-dimensional flood analysis. A flood risk map was generated by taking into consideration both scenarios in which the debris factor associated with water disasters was and was not considered, and predictions were made through random-forest classifications. The results of the prediction and analysis showed that a relatively high flood risk level was found in residential areas with many alleys when the debris factor was taken into account. The prediction results using the random forest were compared with the results of using the flood risk calculation formula, and a high degree of agreement was found. Thus, it was judged that suggested methodology could be used as providing the useful data for performing flood control of each urban drainage basin at a later time.
Through flood prediction and analysis using diverse machine learning, it is possible to determine the danger zones in real-time in the event of a water disaster. The proposed methodology can be said to have high reliability and accuracy, as it uses a database built based on observational data and the results of applying verified numerical analysis models. Its practicality was also demonstrated by presenting the method of utilization with respect to the prediction and analysis results, and it is expected that the prediction model will help speed up the processes of the urban watershed flood control system if it is improved with more basic data. The aim of this study was to demonstrate the diverse uses of various observational data and numerical analysis models in connection with machine learning techniques and that they are accurate enough to be actively applied in practice to defend against flooding.
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