<i>N</i>-soliton solutions and perturbation theory for the derivative nonlinear Schrödinger equation with nonvanishing boundary conditions

Lashkin, Volodymyr M.

doi:10.1088/1751-8113/40/23/008

Cited by 37 publications

(43 citation statements)

References 22 publications

(53 reference statements)

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“…However, its applicability to studying the intermediate behaviour of solutions is restricted to the initial conditions for which the corresponding scattering problem can be solved analytically. To our knowledge, the only non-trivial exact solutions to the DNLS equation obtained so far are different kinds of the N-soliton solutions (see, e.,g., [48][49][50][51]). Since, at present, it is not clear if the scattering problem for the DNLS equation for the initial condition (17) can be solved analytically, the nonlinear evolution of this perturbation was studied numerically [43].…”

Section: Generation Of Large-amplitude Pulses Described By the Dnls Ementioning

confidence: 99%

Freak waves in laboratory and space plasmas

Рудерман

2010

Eur. Phys. J. Spec. Top.

137

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Abstract. Generation of large-amplitude short-lived wave groups from small-amplitude initial perturbations in plasmas is discussed. Two particular wave modes existing in plasmas are considered. The first one is the ion-sound wave. In a plasmas with negative ions it is described by the Gardner equation when the negative ion concentration is close to critical. The results of numerical solution of the Gardner equation with the modulationally unstable initial condition are presented. These results clearly show the possibility of generation of freak ionacoustic waves due to the modulational instability. The second wave mode is the Alfvén wave. When this wave propagates at a small angle with respect to the equilibrium magnetic field, and its wave length is comparable with the ion inertia length, it is described by the DNLS equation. Studying the evolution of an initial perturbation using the linearized DNLS equation shows that the generation of freak Alfvén waves is possible due to linear dispersive focusing. The numerical solution of the DNLS equation reveals that the nonlinear dispersive focusing can also produce freak Alfvén waves.

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Section: Generation Of Large-amplitude Pulses Described By the Dnls Ementioning

confidence: 99%

Freak waves in laboratory and space plasmas

Рудерман

2010

Eur. Phys. J. Spec. Top.

137

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“…Each element of the matrix of n-fold Darboux transformation of this system is expressed by a ratio of (n + 1) × (n + 1) determinant and n × n determinant of eigenfunctions, which implies the determinant representation of q [n] and r [n] generated from known solution q and r. By choosing some special eigenvalues and eigenfunctions according to the reduction conditions q [n] = −(r [n] ) * , the determinant representation of q [n] provides some new solutions of the GI equation. As examples, the breather solutions and rogue wave of the GI is given explicitly by two-fold DT from a periodic "seed" with a constant amplitude.1 regarded as an extension of the NLS when certain higher-order nonlinear effects are taken into account.Comparing with the intensive studies on the DNLSI [4,[7][8][9][10][11][12][13][14][15][16][17][18][19][20] from the point of view of physics and mathematics, there are only few works on the GI including soliton constructed by Darboux transformation(DT) [21], Hamiltonian structures [22], algebro-geometric solutions [23], hierarchy of the GI equation from an extended version of Drinfel'd-Sokolov formulation [24], Wronskian type solution [25] without using affine Lie groups. In order to show more possible physical relevance of the GI equation, and inspired by the importance of breather(BA) solution and rogue wave(RW) of the NLS [26-33], so we shall find these two types of solutions for the GI equation by DT.…”

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confidence: 99%

The rogue wave and breather solution of the Gerdjikov-Ivanov equation

Xu¹,

He²

2012

Journal of Mathematical Physics

149

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Abstract. The Gerdjikov-Ivanov (GI) system of q and r is defined by a quadratic polynomial spectral problem with 2 × 2 matrix coefficients. Each element of the matrix of n-fold Darboux transformation of this system is expressed by a ratio of (n + 1) × (n + 1) determinant and n × n determinant of eigenfunctions, which implies the determinant representation of q[n] and r [n] generated from known solution q and r. By choosing some special eigenvalues and eigenfunctions according to the reduction conditions[n] provides some new solutions of the GI equation. As examples, the breather solutions and rogue wave of the GI is given explicitly by two-fold DT from a periodic "seed" with a constant amplitude.

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“…In this work, we extend the DT by the limit technique, so that it may be iterated at the same spectral parameter. The modified transformation is referred as gDT.The inverse scattering method was used to study DNLS with vanishing background (VBC) and non-vanishing background (NVBC) [3,[20][21][22][23]. The N -bright soliton formula for DNLS was established by Nakamura and Chen by the Hirota bilinear method [24] and the DT for DNLS was constructed by Imai [25] and Steudel [26] (see also [17]).…”

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confidence: 99%