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A novel machine learning-transfer function approach for estimating power absorption in floating wave energy converters

Mohammadreza Torabbeigi, Mohammad Adibzade, Arash Baharifar, Soroush Abolfathi

2025Renewable Energy6 citationsDOIOpen Access PDF

Abstract

Wave energy offers immense potential as a renewable energy source. However, accurately estimating the Total Absorbed Power (TAP) at various sites remains a significant challenge, requiring resource-intensive physical modelling and numerical simulations to capture the complex hydrodynamic behaviour of Wave Energy Converters (WECs) across different designs and wave conditions. To address this, we propose a novel, computationally efficient Machine Learning-Transfer Function (ML-TF) approach to estimate the TAP of Multi-Body Floating WECs (MBFWEC). The methodology integrates frequency-domain and time-domain analyses to generate a sparse dataset of MBFWEC responses under regular waves, which is used to train Machine Learning (ML) models. Wave height, wave period, and Power Take-Off (PTO) damping are the key inputs for predicting the Capture Width Ratio (CWR). Among the models tested, Multi-Layer Perceptron (MLP) model performed best (R 2 = 0.995). This model was then used to derive a high-resolution CWR dataset, with error margins within ±6.11 %, proving its reliability for out-of-range CWR predictions. To extend the model's applicability to irregular wave conditions, a Transfer Function (TF) was developed from the CWR dataset across a desired frequency range. The TAP was subsequently estimated based on the TF, site-specific wave power spectra, and the converter's effective length. Validation using time-history simulations in uni-modal and bi-modal sea states showed excellent accuracy (4 % maximum error), while achieving an 80 % reduction in computational cost. The methodology was further applied in a real-world case study using wave data from three locations in the northern Oman Sea, to evaluate the region's year-round power potential.

Topics & Concepts

Wave energy converterPower (physics)Wave powerEnergy (signal processing)EngineeringFunction (biology)Transfer functionRenewable energyConvertersElectronic engineeringWave heightControl theory (sociology)Wind waveComputer scienceWave modelReliability (semiconductor)PerceptronAlgorithmArtificial neural networkRepresentation (politics)Reduction (mathematics)Range (aeronautics)Multilayer perceptronElectricity generationSignificant wave heightEnergy transformationFrequency responseSurrogate modelMarine energyPower functionWave and Wind Energy SystemsOcean Waves and Remote SensingWind Energy Research and Development
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