Abstract
The data recorded in optical fiber and in hydrodynamic experiments reported the pioneering observation of nonlinear waves with spatiotemporal localization similar to the Peregrine soliton are examined by using nonlinear spectral analysis. Our approach is based on the integrable nature of the one-dimensional focusing nonlinear Schrödinger equation (1D-NLSE) that governs at leading order the propagation of the optical and hydrodynamic waves in the two experiments. Nonlinear spectral analysis provides certain spectral portraits of the analyzed structures that are composed of bands lying in the complex plane. The spectral portraits can be interpreted within the framework of the so-called finite gap theory (or periodic inverse scattering transform). In particular, the number N of bands composing the nonlinear spectrum determines the genus g=N-1 of the solution that can be viewed as a measure of complexity of the space-time evolution of the considered solution. Within this setting the ideal, rational Peregrine soliton represents a special, degenerate genus 2 solution. While the fitting procedures previously employed show that the experimentally observed structures are quite well approximated by the Peregrine solitons, nonlinear spectral analysis of the breathers observed both in the optical fiber and in the water tank experiments reveals that they exhibit spectral portraits associated with more general, genus 4 finite-gap NLSE solutions. Moreover, the nonlinear spectral analysis shows that the nonlinear spectrum of the breathers observed in the experiments slowly changes with the propagation distance, thus confirming the influence of unavoidable perturbative higher-order effects or dissipation in the experiments.
Highlights
Nonlinear integrable partial differential equations (PDEs) represent an important class of wave equations that are relevant to many fields of physics and applied mathematics [1,2,3]
Notable examples include the one-dimensional nonlinear Schrödinger equation (1D-NLSE), the Korteweg de Vries (KdV) equation, and the Benjamin-Ono equation. These integrable PDEs can be solved by using the inverse scattering transform (IST) method [4,5], and they exhibit soliton solutions, the most celebrated one being the propagation-invariant hyperbolic secant soliton first discovered by Zabusky and Kruskal through numerical simulations of the KdV equation [6,7]
We have analyzed the data recorded in an optical fiber experiment [12] and in a hydrodynamic experiment [15] that have reported the observation of solitons on finite background (SFB) having properties of localization in space and time similar to those of the Peregrine soliton (PS)
Summary
Nonlinear integrable partial differential equations (PDEs) represent an important class of wave equations that are relevant to many fields of physics and applied mathematics [1,2,3]. Some prototypical breather solutions of the focusing 1D-NLSE like the Peregrine soliton (PS), the Kuznetsov-Ma (KM) soliton, or the Akhmediev breather (AB) were found around the ’80s [8,9,10,11] These specific SFB have been experimentally observed in a series of optics and hydrodynamic experiments that have been realized about 30 years later, around 2010 [12,13,14,15,16]. Note that in addition to the PS, there is an infinite hierarchy of higher-order breather solutions of the 1D-NLSE that are localized both in space and time while having a high peak amplitude [22,23] These higher-order breather solutions have been observed in some recent optics and hydrodynamic experiments [24,25,26]. THE INVERSE SCATTERING TRANSFORM METHOD FOR THE NONLINEAR SPECTRAL ANALYSIS OF THE PEREGRINE SOLITON
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