In mathematics, the inverse scattering transform is a method for solving some non-linear partial differential equations. It is one of the most important developments in mathematical physics in the past 40 years. The method is a non-linear analogue, and in some sense generalization, of the Fourier transform, which itself is applied to solve many linear partial differential equations. The name "inverse scattering method" comes from the key idea of recovering the time evolution of a potential from the time evolution of its scattering data: inverse scattering refers to the problem of recovering a potential from its scattering matrix, as opposed to the direct scattering problem of finding the scattering matrix from the potential. The inverse scattering transform may be applied to many of the so-called exactly solvable models, that is to say completely integrable infinite dimensional systems.
The Korteweg–de Vries equation is a nonlinear, dispersive, evolution partial differential equation for a functionu; of two real variables, one space variable x and one time variable t : with and denoting partial derivatives with respect tot and x, respectively. To solve the initial value problem for this equation where is a known function of x, one associates to this equation the Schrödinger eigenvalue equation where is an unknown function of t and x and u is the solution of the Korteweg–de Vries equation that is unknown except at. The constant is an eigenvalue. From the Schrödinger equation we obtain Substituting this into the Korteweg–de Vries equation and integrating gives the equation where C and D are constants.
Method of solution
Step 1. Determine the nonlinear partial differential equation. This is usually accomplished by analyzing the physics of the situation being studied. Step 2. Employ forward scattering. This consists in finding the Lax pair. The Lax pair consists of two linear operators, and, such that and. It is extremely important that the eigenvalue be independent of time; i.e. Necessary and sufficient conditions for this to occur are determined as follows: take the time derivative of to obtain Plugging in for yields Rearranging on the far right term gives us Thus, Since, this implies that if and only if This is Lax's equation. In Lax's equation is that is the time derivative of precisely where it explicitly depends on. The reason for defining the differentiation this way is motivated by the simplest instance of, which is the Schrödinger operator : where u is the "potential". Comparing the expression with shows us that thus ignoring the first term. After concocting the appropriate Lax pair it should be the case that Lax's equation recovers the original nonlinear PDE. Step 3. Determine the time evolution of the eigenfunctions associated to each eigenvalue, the norming constants, and the reflection coefficient, all three comprising the so-called scattering data. This time evolution is given by a system of linear ordinary differential equations which can be solved. Step 4. Perform the inverse scattering procedure by solving the Gelfand–Levitan–Marchenko integral equation, a linear integral equation, to obtain the final solution of the original nonlinear PDE. All the scattering data is required in order to do this. If the reflection coefficient is zero, the process becomes much easier. This step works if is a differential or difference operator of order two, but not necessarily for higher orders. In all cases however, the inverse scattering problem is reducible to a Riemann–Hilbert factorization problem. for either approach. See Marchenko
