Korteweg-de Vries equation

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The Korteweg-de Vries (KdV) equation is

\partial_t u + \partial_x^3 u + 6u\partial_x u = 0.

The factor of 6 is convenient for reasons of complete integrability, but can easily be scaled out if desired.

The equation is completely integrable, and has infinitely many conserved quantities. Indeed, for each non-negative integer k, there is a conserved quantity which is roughly equivalent to the Hk norm of u.

The KdV equation has been studied on the line, on the circle, and on the half-line.

The KdV equation is the first non-trivial equation on the KdV hierarchy and is the most famous member of the family of KdV-type equations.

Symplectic Structures

At least two distinct Hamiltonian representations of the completely integrable Korteweg-de Vries equation are known. The standard Fadeev-Zakharov representation uses Hamiltonian H[u] = \int u_x^2 + u^3 dx with symplectic phase space H − 1 / 2 shared by other KdV-type equations. F. Magri has shown Mag78 that KdV may also be represented using the Hamiltonian H[u] = \int u^2 dx. The natural phase space associated to the Magri representation of KdV appears to be H − 3 / 2 but details need to be worked out.

Symplectic nonsqueezing of the KdV flow in the associated symplectic phase space H_0^{-1/2} (\mathbb{T}) was established in CoKeStTkTa2004. Whether nonsqueezing also holds in H − 3 / 2 using the Magri representation is unknown. The periodic KdV flow is not known to be globally well-posed in H − 3 / 2.

Question: Do there exist other symplectic representations of KdV besides the Fadeev-Zakharov and Magri representations? Colliand 12:01, 14 September 2006 (EDT)
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