Note on the modified nonlinear Schrödinger equation for deep water waves

The modified nonlinear Schrijdinger equation of Dysthe [Proc. Roy. Sot. Land. Sex A, 369, 105-114 (1979)] is extended by relaxing the narrow bandwidth constraint to make it more suitable for application to a realistic ocean wave spectrum. The new equation limits the bandwidth of unstable wave number

We study the long-time behavior of solutions of the nonlinear Schrödinger equation in one space dimension for initial conditions in a small neighborhood of a stable solitary wave. Under some hypothesis on the structure of the spectrum of the linearized operator, we prove that, asymptotically in time

We develop the nonlinear Schrödinger method for fast and accurate computation of the velocity and acceleration fields under irregular ocean surface waves on finite depth, and apply it to laboratory and field data.

The modified nonlinear Schr€ o odinger (MNLS) equation is a model equation for the propagation of ultra-fast pulses in long-haul optical fiber transmission systems. Here we identify the linearized instabilities of plane wave solutions to both the defocusing and the focusing MNLS equation. Extending

The soliton perturbation theory is used to study the solitons that are governed by the modified nonlinear Schro ¨dinger's equation. The adiabatic parameter dynamics of the solitons in presence of the perturbation terms are obtained. In particular, the nonlinear gain (damping) and filters or the coef