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Nonlinear wave evolution with data-driven breaking

Debbie Eeltink, Hubert Branger, Christopher Luneau, Yuchen He, Amin Chabchoub, Jérôme Kasparian, Ton S. van den Bremer, Themistoklis P. Sapsis

2022Nature Communications59 citationsDOIOpen Access PDF

Abstract

Wave breaking is the main mechanism that dissipates energy input into ocean waves by wind and transferred across the spectrum by nonlinearity. It determines the properties of a sea state and plays a crucial role in ocean-atmosphere interaction, ocean pollution, and rogue waves. Owing to its turbulent nature, wave breaking remains too computationally demanding to solve using direct numerical simulations except in simple, short-duration circumstances. To overcome this challenge, we present a blended machine learning framework in which a physics-based nonlinear evolution model for deep-water, non-breaking waves and a recurrent neural network are combined to predict the evolution of breaking waves. We use wave tank measurements rather than simulations to provide training data and use a long short-term memory neural network to apply a finite-domain correction to the evolution model. Our blended machine learning framework gives excellent predictions of breaking and its effects on wave evolution, including for external data.

Topics & Concepts

Nonlinear systemBreaking wavePhysicsComputer scienceStatistical physicsWave propagationQuantum mechanicsOcean Waves and Remote SensingMeteorological Phenomena and SimulationsTropical and Extratropical Cyclones Research
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