Completely integrable: Difference between revisions
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A few nonlinear dispersive and wave equations are lucky enough to be completely integrable. | |||
A few nonlinear dispersive and wave equations are lucky enough to be | |||
completely integrable in the sense that there exist a Lax pair formulation of the equation. | |||
This means in particular that they enjoy infinitely many conservation laws. | |||
In many cases these conservation laws provide control on high Sobolev | |||
norms which seems to be a quite expetional event. The existence of a Lax pair | |||
allows to apply (at least formally) inverse scattering techniques to solve | |||
a completely integrable equation. Some nonlinear PDE's as the KdV posed | |||
on the circle are integrable in the sense of Loiuville-Arnold which | |||
means that there exist action/angle variables associated to the equation. | |||
== List of completely integrable nonlinear dispersive and wave equations == | == List of completely integrable nonlinear dispersive and wave equations == | ||
Revision as of 12:59, 4 August 2006
A few nonlinear dispersive and wave equations are lucky enough to be
completely integrable in the sense that there exist a Lax pair formulation of the equation.
This means in particular that they enjoy infinitely many conservation laws.
In many cases these conservation laws provide control on high Sobolev
norms which seems to be a quite expetional event. The existence of a Lax pair
allows to apply (at least formally) inverse scattering techniques to solve
a completely integrable equation. Some nonlinear PDE's as the KdV posed
on the circle are integrable in the sense of Loiuville-Arnold which
means that there exist action/angle variables associated to the equation.
