Cauchy Problem

A Cauchy problem in mathematics asks for the solution of a partial differential equation that satisfies certain conditions which are given on a hypersurface in the domain. A Cauchy problem can be an initial value problem or a boundary value problem (for this case see also Cauchy boundary condition), but it can be none of them. They are named after Augustin Louis Cauchy.

Suppose that the partial differential equation is defined on Rn and consider a smooth manifold S ⊂ Rn of dimension n − 1 (S is called the Cauchy surface). Then the Cauchy problem consists of finding the solution u of the differential equation which satisfies

$\begin{align} u(x) &= f_0(x) \qquad && \text{for all } x\in S; \\ \frac{\part^k u(x)}{\part n^k} &= f_k(x) \qquad && \text{for } k=1,\ldots,\kappa-1 \text{ and all } x\in S, \end{align}$

where are given functions defined on the surface (collectively known as the Cauchy data of the problem), n is a normal vector to S, and κ denotes the order of the differential equation.

The Cauchy–Kowalevski theorem says that Cauchy problems have unique solutions under certain conditions, the most important of which being that the Cauchy data and the coefficients of the partial differential equation be real analytic functions.

Famous quotes containing the word problem:

“Great speeches have always had great soundbites. The problem now is that the young technicians who put together speeches are paying attention only to the soundbite, not to the text as a whole, not realizing that all great soundbites happen by accident, which is to say, all great soundbites are yielded up inevitably, as part of the natural expression of the text. They are part of the tapestry, they aren’t a little flower somebody sewed on.”
—Peggy Noonan (b. 1950)