Date of Award
12-2024
Degree Type
Masters Thesis
Degree Name
Master of Science (MS)
School
Ocean Science and Engineering
Committee Chair
Dr. Md Mamunur Rashid
Committee Chair School
Ocean Science and Engineering
Committee Member 2
Dr.Wei Wu
Committee Member 2 School
Ocean Science and Engineering
Committee Member 3
Dr.Robert Leaf
Committee Member 3 School
Ocean Science and Engineering
Committee Member 4
Dr. Mustafa Kemal Cambazoglu
Committee Member 4 School
Ocean Science and Engineering
Abstract
Storm surges cause coastal flooding, one of the most devastating coastal hazards. Accurate modeling of storm surges is essential for predicting and mitigating these impacts. Traditional approaches model surges at individual tide gauges and often focus on daily time scales, leading to data redundancy and limiting their ability to capture sub-daily variability. This study addresses these limitations using deep learning (DL) algorithms to model hourly surges simultaneously at multiple tide gauges along the U.S. East Coast and Gulf of Mexico. Three algorithms, Convolutional Neural Network (CNN), Long Short-Term Memory (LSTM), and a hybrid ConvLSTM are employed to model surges using atmospheric variables (e.g., sea level pressure and winds) as predictors. ConvLSTM outperforms the others in predicting the overall variability of surges, extreme surge events, and statistical attributes of extreme surge hydrographs. The model’s efficiency is comparable to that of existing data-driven and hydrodynamic models in reproducing surges. The study also applies DL models to project future changes in storm surge statistics, using predictor variables from the GFDL-ESM4 global climate model (GCM) under two climate scenarios. In general, there will be increases in the mean and extreme surges at some TGs, whereas the others will experience a reduction. However, it is difficult to draw robust conclusive remarks on the future changes in storm surges as the study considers only one GCM. Therefore, considering more GCMs to cover the whole range of uncertainty and computing the uncertainty in the future changes of storm surge statistics is crucial and proposed as a future extension of this research.
ORCID ID
0000-0001-5756-9706
Copyright
Md Abu Zafor, 2024
Recommended Citation
Zafor, Md Abu, "Modeling Hourly Storm Surges using Deep Learning Techniques" (2024). Master's Theses. 1082.
https://aquila.usm.edu/masters_theses/1082
Included in
Atmospheric Sciences Commons, Climate Commons, Meteorology Commons, Oceanography Commons, Other Oceanography and Atmospheric Sciences and Meteorology Commons