Date of Completion
8-3-2020
Embargo Period
8-3-2020
Keywords
Long Island sound, wave heights, MCMC, INLA, logistic regression, GLM, DGLM, quantile reqression, expectile regression, hqreg, SALES
Major Advisor
Nalini Ravishanker
Associate Advisor
Haim Bar
Associate Advisor
James O'Donnell
Field of Study
Statistics
Open Access
Open Access
Abstract
Current marine science methods for modeling wave data typically assume that wave height distributions belong to limited class within the exponential family. Alternatively, models emphasize physics principles over statistical methods. In this dissertation, we investigate the predictive power of wave height histories as well as exogenous predictors. We develop binary time series models for wave height over a threshold in both frequentist and Bayesian frameworks. Within the Bayesian framework, we fit Dynamic Generalized Linear Models (DGLM) using Integrated Nested Laplace Approximations and demonstrate advantages over classical methods. We further investigate the quantiles and expectiles of the continuous- valued wave height time series. Models with high lag orders are and hundreds of predictors are considered. Using regularized quantile and expectile regression with the Elastic Net penalty, we fit sparse models to characterize the upper tail of the wave height distribution and offer predictions of high quantiles and expectiles as a function of local sea state.
Recommended Citation
Shaffer, Ellis, "Temporal Modeling Frameworks for Coastal Wave Heights" (2020). Doctoral Dissertations. 2605.
https://digitalcommons.lib.uconn.edu/dissertations/2605