KdV hierarchy

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Template:Short description In mathematics, the KdV hierarchy is an infinite sequence of partial differential equations which contains the Korteweg–de Vries equation.

Details

Let T be translation operator defined on real valued functions as T(g)(x)=g(x+1). Let 𝒞 be set of all analytic functions that satisfy T(g)(x)=g(x), i.e. periodic functions of period 1. For each g𝒞, define an operator Lg(ψ)(x)=ψ(x)+g(x)ψ(x) on the space of smooth functions on . We define the Bloch spectrum g to be the set of (λ,α)×* such that there is a nonzero function ψ with Lg(ψ)=λψ and T(ψ)=αψ. The KdV hierarchy is a sequence of nonlinear differential operators Di:𝒞𝒞 such that for any i we have an analytic function g(x,t) and we define gt(x) to be g(x,t) and Di(gt)=ddtgt, then g is independent of t.

The KdV hierarchy arises naturally as a statement of Huygens' principle for the D'Alembertian.[1][2]

Explicit equations for first three terms of hierarchy

The first three partial differential equations of the KdV hierarchy are ut0=uxut1=6uuxuxxxut2=10uuxxx20uxuxx30u2uxuxxxxx. where each equation is considered as a PDE for u=u(x,tn) for the respective n.[3]

The first equation identifies t0=x and t1=t as in the original KdV equation. These equations arise as the equations of motion from the (countably) infinite set of independent constants of motion In[u] by choosing them in turn to be the Hamiltonian for the system. For n>1, the equations are called higher KdV equations and the variables tn higher times.

Application to periodic solutions of KdV

File:Cnoidal wave m=0.9.svg
Cnoidal wave solution to the Korteweg–De Vries equation, in terms of the square of the Jacobi elliptic function cn (and with value of the parameter m = 0.9).

One can consider the higher KdVs as a system of overdetermined PDEs for u=u(t0=x,t1=t,t2,t3,). Then solutions which are independent of higher times above some fixed n and with periodic boundary conditions are called finite-gap solutions. Such solutions turn out to correspond to compact Riemann surfaces, which are classified by their genus g. For example, g=0 gives the constant solution, while g=1 corresponds to cnoidal wave solutions.

For g>1, the Riemann surface is a hyperelliptic curve and the solution is given in terms of the theta function.[4] In fact all solutions to the KdV equation with periodic initial data arise from this construction (Manakov, Novikov & Pitaevskii et al. 1984).

See also

References

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Sources

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External links