The Symmetries of Solitons

TL;DR

This paper provides an expository overview of soliton mathematics, detailing the inverse scattering method, hidden symmetries, and developments from early experiments to modern synthesis involving loop-groups.

Contribution

It synthesizes historical developments and explains the inverse scattering method and hidden symmetries of soliton equations in a comprehensive, pedagogical manner.

Findings

Detailed explanation of inverse scattering for KdV and NLS equations

Connection of soliton symmetries with loop-groups and dressing transformations

Historical overview from Fermi-Pasta-Ulam experiments to modern theory

Abstract

This paper is an expository account of the development of soliton mathematics, from its inception in famous numerical experiments of Fermi-Pasta-Ulam and Zabusky-Kruskal to the recent synthesis of Terng-Uhlenbeck (dg-ga/9707004) that explains hidden symmetries of soliton equations in terms of loop-groups acting by dressing transformations. The inverse scattering method is explained in detail, first using inverse scattering for the Schroedinger equation to solve the IVP for the KdV equation (the original application) and then using inverse scattering for the Zero Curvature Lax Equation to solve the IVP for the Nonlinear Schroedinger equation, and more generally other integrable PDE arising from the ZS-AKNS scheme devised by Zakharov and Shabat and by Ablowitz, Kaup, Newell and Segur. The paper is a revised version of notes from a series of Rudolf Lipschitz Lectures delivered by the author at Bonn University in January and February of 1997.