Universality of the amplitude shift in fast two-pulse collisions in weakly perturbed linear physical systems

TL;DR

This paper shows that amplitude shifts in fast two-pulse collisions within weakly perturbed linear systems behave universally like soliton interactions, regardless of initial pulse shape, across different physical models.

Contribution

It reveals the universal soliton-like behavior of amplitude shifts in linear systems with weak nonlinear dissipation, extending the understanding beyond nonlinear soliton systems.

Findings

Amplitude shifts follow a universal form similar to nonlinear soliton collisions.

The universal behavior is independent of initial pulse shape.

Numerical simulations confirm analytical predictions across various pulse types.

Abstract

We demonstrate that the amplitude shifts in fast two-pulse collisions in perturbed linear physical systems with weak nonlinear dissipation exhibit universal soliton-like behavior. The behavior is demonstrated for linear optical waveguides with weak cubic loss and for systems described by linear diffusion-advection models with weak quadratic loss. We show that in both systems, the expressions for the collision-induced amplitude shifts due to the nonlinear loss have the same form as the expression obtained for a fast collision between two solitons of the nonlinear Schr\"odinger equation in the presence of weak cubic loss. Furthermore, we show that the expressions for the amplitude shifts are universal in the sense that they are independent of the exact details of the initial pulse shapes. We demonstrate the universal soliton-like behavior of the collision-induced amplitude shifts by carrying out numerical simulations with the two perturbed coupled linear evolution models with three different initial conditions corresponding to pulses with exponentially decreasing tails, pulses with power-law decreasing tails, and pulses that are initially nonsmooth and that develop significant tails during the collision. In all six cases we observe very good agreement between the analytic predictions for the amplitude shifts and the results of the numerical simulations.