Novel optimized deep learning algorithms and explainable artificial intelligence for storm surge susceptibility modeling and management in a flood-prone island

Sagar Island, located in the Indian Sundarbans Delta, is extremely vulnerable to storm surge flooding. Therefore, there is a need for a precise model to assess its susceptibility to storm surges, which is essential for efficient coastal management and reducing the risk of disasters. Traditional mode...

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Vydáno v:Natural hazards (Dordrecht) Ročník 120; číslo 6; s. 5099 - 5128
Hlavní autoři: Alshayeb, Mohammed J., Hang, Hoang Thi, Shohan, Ahmed Ali A., Bindajam, Ahmed Ali
Médium: Journal Article
Jazyk:angličtina
Vydáno: Dordrecht Springer Netherlands 01.04.2024
Springer Nature B.V
Témata:
Accuracy
Additives
Algorithms
Artificial intelligence
Artificial neural networks
Bayesian analysis
Bayesian theory
Civil Engineering
Coastal management
Coastal zone
Coastal zone management
Collinearity
Competitors
Cyclone tracks
Deep learning
Disaster management
Disaster risk
Disasters
Earth and Environmental Science
Earth Sciences
Environmental Management
Explainable artificial intelligence
Flood management
Floods
Geophysics/Geodesy
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Machine learning
Mathematical models
Model accuracy
Modelling
Natural Hazards
Neural networks
Optimization
Original Paper
Permutations
Prediction models
Probability theory
Rainfall
Risk reduction
Robustness
Storm surges
Storms
Susceptibility
Tidal waves
Sagar Island
Deep learning
Storm surge
Sagar Island
Explainable AI
Bayesian optimization
LightGBM
ISSN:0921-030X, 1573-0840
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Popis
Shrnutí:Sagar Island, located in the Indian Sundarbans Delta, is extremely vulnerable to storm surge flooding. Therefore, there is a need for a precise model to assess its susceptibility to storm surges, which is essential for efficient coastal management and reducing the risk of disasters. Traditional modeling methods often lack the capability to consider the intricate relationships between various influencing factors. This study aims to advance the field by developing robust deep learning (DL) models for storm surge susceptibility prediction, specifically incorporation of Bayesian optimization with DL models and implementing Explainable Artificial Intelligence (XAI) methods for model interpretation and data-driven management. Storm surge susceptibility in Sagar Island presents a critical problem requiring advanced predictive modeling. We employ Bayesian Optimization for hyperparameter tuning in Deep Neural Networks (DNN), 1D Convolutional Neural Networks (CNN), and LightGBM models, focusing on 11 variables with low multi-collinearity. Additionally, we applied Explainable AI techniques such as SHapley Additive exPlanations (SHAP) and permutation importance for model interpretability. DNN achieved the highest accuracy of 97.75%, with F1-score at 97.85%. LightGBM and CNN were close competitors with an accuracy of 97.5%. DNN’s true positive rate was 95%, compared to CNN’s 94% and LightGBM’s 93%. In the susceptibility mapping analysis, the CNN detected areas categorized as ‘Very Low’ and ‘Very High’ susceptibility, constituting 65.12% of the study area and covering 156.88 km² and 11.38% covering 11.38 km², respectively. Similarly, LightGBM exhibited a comparable pattern, but with a more pronounced representation of ‘High’ susceptibility zones, spanning 22.61 km², predominantly across the coastal and central regions of Sagar Island. Feature importance assessed through SHAP revealed “Rainfall” as 40% more impactful than “Cyclone Track.” While all three models demonstrated robust performance, DNN emerged as marginally superior in most evaluated metrics. Our study provides valuable insights for targeted storm surge management strategies in Sagar Island, combining high predictive accuracy with model interpretability.
Bibliografie:ObjectType-Article-1
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ISSN:0921-030X
1573-0840
DOI:10.1007/s11069-024-06414-6