Your search keyword '"significant wave height prediction"' showing total 3 results

1. Coastal zone significant wave height prediction by supervised machine learning classification algorithms

Author

George Papanastasiou, Constantine Michailides, Demetris Demetriou, and Toula Onoufriou

Subjects

Environmental Engineering, Nowcasting, Computer science, Decision tree, 020101 civil engineering, Ocean Engineering, 02 engineering and technology, Overfitting, 01 natural sciences, 010305 fluids & plasmas, 0201 civil engineering, 0103 physical sciences, Machine learning, Redundancy (engineering), Feature (machine learning), Gini impurity index, Classification algorithms, Artificial neural network, Electrical Engineering - Electronic Engineering - Information Engineering, Statistical classification, Engineering and Technology, Significant wave height, Algorithm, Neural networks, Significant wave height prediction

Abstract

Explicit wave models and expensive sensor equipment capable of predicting and measuring wave parameters often carry a prohibitive computational and financial expense. To counter this, this paper proposes an alternative method for nowcasting coastal zone significant wave heights through the joint use of meteorological and structural data in the training of supervised machine learning models. In testing the hypothesis that structural data can improve model classification, artificial neural network and decision tree models were developed, trained and tested on field data recorded on a coastal jetty located in the southern coasts of Cyprus. A comprehensive investigation of the different models yields that the joint use of meteorological and structural features can improve classification performance, regardless of the network choice. It is also demonstrated that redundancy of training parameters could inject unwanted overfitting, reducing model generalization. To address this, a method for quantifying feature importance has been proposed by exploiting the nature of decision tree algorithms and the Gini impurity index, reaffirming that structural features do indeed benefit model classification. These results highlight the potential of tapping into the untapped pool of structural data for significant wave height prediction, paving the way for new research to be undertaken in this direction.

Published

2021

2. Nowcasting significant wave height by hierarchical machine learning classification

Author

Toula Onoufriou, Constantine Michailides, George Papanastasiou, and Demetris Demetriou

Subjects

Hyperparameter, Flexibility (engineering), Classification algorithms, Environmental Engineering, Hierarchy (mathematics), Nowcasting, business.industry, Computer science, Hierarchical machine learning, Ocean Engineering, Machine learning, computer.software_genre, Civil Engineering, Hierarchical decomposition, Classification based modeling, Ocean engineering, Statistical classification, Classifier (linguistics), Engineering and Technology, Model development, Artificial intelligence, business, Significant wave height, computer, Significant wave height prediction

Abstract

This paper proposes an alternative method for nowcasting significant wave height (Hs) through the development of hierarchical machine learning classification models. In testing the hypothesis that hierarchical classification can improve Hs prediction, flat and hierarchical classifiers were developed and tested on field-data recorded on a coastal jetty located in the southern coasts of Cyprus. A comprehensive investigation of the performance of flat over hierarchical classification models yields that the proposed method provides greater flexibility throughout the model development stages. This flexibility is attributed to the manipulation of data before training, optimization of classifier's hyperparameters during training, and the curtailment of features post-training at each level of the hierarchy. It is demonstrated that, the hierarchical approach resulted in better classification performance across a plethora of performance metrics established for a comprehensive comparison. It is also shown that the increased performance of the proposed approach comes at the expense of complexity arising from performing computationally expensive operations and the requirement for development of multiple local classifiers. Still, the increased classification performance of the hierarchical approach highlights the potential of this original method and the requirement for a rigid framework to be constructed for the development of hierarchical models for Hs prediction.

Published

2021

3. Coastal zone significant wave height prediction by supervised machine learning classification algorithms.

Author

Demetriou, Demetris, Michailides, Constantine, Papanastasiou, George, and Onoufriou, Toula

Subjects

*DECISION trees, *SUPERVISED learning, *COASTS, *CLASSIFICATION algorithms, *MACHINE learning, *ARTIFICIAL neural networks

Abstract

Explicit wave models and expensive sensor equipment capable of predicting and measuring wave parameters often carry a prohibitive computational and financial expense. To counter this, this paper proposes an alternative method for nowcasting coastal zone significant wave heights through the joint use of meteorological and structural data in the training of supervised machine learning models. In testing the hypothesis that structural data can improve model classification, artificial neural network and decision tree models were developed, trained and tested on field data recorded on a coastal jetty located in the southern coasts of Cyprus. A comprehensive investigation of the different models yields that the joint use of meteorological and structural features can improve classification performance, regardless of the network choice. It is also demonstrated that redundancy of training parameters could inject unwanted overfitting, reducing model generalization. To address this, a method for quantifying feature importance has been proposed by exploiting the nature of decision tree algorithms and the Gini impurity index, reaffirming that structural features do indeed benefit model classification. These results highlight the potential of tapping into the untapped pool of structural data for significant wave height prediction, paving the way for new research to be undertaken in this direction. • Structural acceleration data can be leveraged to obtain better classification models, aiding the prediction of significant wave height. • Neural networks and tree ensemble classification algorithms are effective in the prediction of significant wave height. • Network complexity and structural feature redundancy increases chances of overfitting, compromising model generalization. • Gini impurity index is a viable feature importance indicator, aiding the robustness of the models post feature curtailement. [ABSTRACT FROM AUTHOR]

Published

2021