Yawen Zang , Huimin Wang , Zhenzhen Liu , Jing Huang
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引用次数: 0
Abstract
Scientific and accurate assessment of risk influencing factors are crucial for flood risk management. This paper aims to propose a new comprehensive framework for flood risk assessment in coastal cities. Firstly, considering the flood characteristics of coastal cities and the impact of floods on urban spatial structure, a flood risk assessment indicator system for coastal cities was established. Secondly, combining game combination weighting and Iterative self-organizing data analysis technique algorithm (GCW_ISODATA) for flood risk assessment. Finally, based on the explainable machine learning techniques, the sensitivity of indicators to flood risk was analyzed. The results indicated that coastal floods are more destructive than rainfall and river floods. Moreover, the indicator weighting and threshold division have a direct impact on the rationality of flood risk, GCW_ISODATA method performs well in Accuracy, F1 score, and AUC, especially with the highest AUC among all methods. Entropy weight method and GCW are significantly superior to Analytic Hierarchy Process (AHP) method, and ISODATA method usually performs better than the K-Means and Natural Break method. Furthermore, the sensitivity of indicators to flood risk reveals that differences in economic, social, and environmental characteristics across regions affect the actual impact of these indicators, leading to the sensitivity of the same indicator to flood risk varies significantly across different regions. It is expected that the framework proposed in this study can be used to explore flood risk impact on other coastal cities.
期刊介绍:
The International Journal of Disaster Risk Reduction (IJDRR) is the journal for researchers, policymakers and practitioners across diverse disciplines: earth sciences and their implications; environmental sciences; engineering; urban studies; geography; and the social sciences. IJDRR publishes fundamental and applied research, critical reviews, policy papers and case studies with a particular focus on multi-disciplinary research that aims to reduce the impact of natural, technological, social and intentional disasters. IJDRR stimulates exchange of ideas and knowledge transfer on disaster research, mitigation, adaptation, prevention and risk reduction at all geographical scales: local, national and international.
Key topics:-
-multifaceted disaster and cascading disasters
-the development of disaster risk reduction strategies and techniques
-discussion and development of effective warning and educational systems for risk management at all levels
-disasters associated with climate change
-vulnerability analysis and vulnerability trends
-emerging risks
-resilience against disasters.
The journal particularly encourages papers that approach risk from a multi-disciplinary perspective.