Quantification and prediction of extreme events in a one-dimensional nonlinear dispersive wave model

The aim of this work is the quantification and prediction of rare events characterized by extreme intensity in nonlinear waves with broad spectra. We consider a one-dimensional nonlinear model with deep-water waves dispersion relation, the Majda–McLaughlin–Tabak (MMT) model, in a dynamical regime th...

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Bibliographic Details
Published in:Physica. D 2014-07, Vol.280-281, p.48-58
Main Authors: Cousins, Will, Sapsis, Themistoklis P.
Format: Article
Language:English
Subjects:
Broadband
Dispersive nonlinear waves
Energy transfer
Instability
Intermittent instabilities
Mathematical models
Nonlinear energy transfers
Nonlinearity
Position (location)
Prediction of extreme events
Probabilistic quantification of rare events
Rogue waves
Wave dispersion
Wave propagation
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Summary:The aim of this work is the quantification and prediction of rare events characterized by extreme intensity in nonlinear waves with broad spectra. We consider a one-dimensional nonlinear model with deep-water waves dispersion relation, the Majda–McLaughlin–Tabak (MMT) model, in a dynamical regime that is characterized by a broadband spectrum and strong nonlinear energy transfers during the development of intermittent events with finite-lifetime. To understand the energy transfers that occur during the development of an extreme event we perform a spatially localized analysis of the energy distribution along different wavenumbers by means of the Gabor transform. A statistical analysis of the Gabor coefficients reveals (i) the low-dimensionality of the intermittent structures, (ii) the interplay between non-Gaussian statistical properties and nonlinear energy transfers between modes, as well as (iii) the critical scales (or critical Gabor coefficients) where a critical amount of energy can trigger the formation of an extreme event. We analyze the unstable character of these special localized modes directly through the system equation and show that these intermittent events are due to the interplay of the system nonlinearity, the wave dispersion, and the wave dissipation which mimics wave breaking. These localized instabilities are triggered by random localizations of energy in space, created by the dispersive propagation of low-amplitude waves with random phase. Based on these properties, we design low-dimensional functionals of these Gabor coefficients that allow for the prediction of the extreme event well before the nonlinear interactions begin to occur. •Probabilistic analysis of extreme events in a nonlinear dispersive wave model.•Analytical characterization trigger condition for extreme events.•Characterization of the energy transfers through a Gabor basis, localized approach.•Formulation of a predictive scheme for extreme events.
ISSN:0167-2789
1872-8022
DOI:10.1016/j.physd.2014.04.012