Response Component Analysis for Sea State Estimation Using Artificial
Neural Networks and Vessel Response Spectral Data
- URL: http://arxiv.org/abs/2205.02375v1
- Date: Thu, 5 May 2022 00:35:58 GMT
- Title: Response Component Analysis for Sea State Estimation Using Artificial
Neural Networks and Vessel Response Spectral Data
- Authors: Nathan K. Long, Daniel Sgarioto, Matthew Garratt, Karl Sammut
- Abstract summary: This study focuses on a model-free machine learning approach to SAWB-based sea state estimation (SSE)
Results showed a strong correlation between heave responses and significant wave height estimates.
The designed SSE method shows promise for future adaptation to mobile SSE systems using the SAWB approach.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: The use of the `ship as a wave buoy analogy' (SAWB) provides a novel means to
estimate sea states, where relationships are established between causal wave
properties and vessel motion response information. This study focuses on a
model-free machine learning approach to SAWB-based sea state estimation (SSE),
using neural networks (NNs) to map vessel response spectral data to statistical
wave properties.
Results showed a strong correlation between heave responses and significant
wave height estimates, whilst the accuracy of mean wave period and wave heading
predictions were observed to improve considerably when data from multiple
vessel degrees of freedom (DOFs) was utilized. Overall, 3-DOF (heave, pitch and
roll) NNs for SSE were shown to perform well when compared to existing SSE
approaches that use similar simulation setups. Given the information-dense
statistical representation of vessel motion responses in spectral form, as well
as the ability of NNs to effectively model complex relationships between
variables, the designed SSE method shows promise for future adaptation to
mobile SSE systems using the SAWB approach.
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