Suppose that F is a vector field: that is, a vector-valued function with Cartesian coordinates ; and x a parametric curve with Cartesian coordinates,x2,...,xn). Then x is an integral curve of F if it is a solution of the following autonomous system of ordinary differential equations: Such a system may be written as a single vector equation This equation says that the vector tangent to the curve at any point x along the curve is precisely the vector F, and so the curve x is tangent at each point to the vector field F. If a given vector field is Lipschitz continuous, then the Picard–Lindelöf theorem implies that there exists a unique flow for small time.
Let M be a Banach manifold of classCr with r ≥ 2. As usual, TM denotes the tangent bundle of M with its natural projectionπM : TM → M given by A vector field on M is a cross-section of the tangent bundle TM, i.e. an assignment to every point of the manifold M of a tangent vector to M at that point. Let X be a vector field on M of class Cr−1 and let p ∈ M. An integral curve for X passing through p at time t0 is a curve α : J → M of class Cr−1, defined on an open intervalJ of the real lineR containing t0, such that
The above definition of an integral curve α for a vector field X, passing through p at time t0, is the same as saying that α is a local solution to the ordinary differential equation/initial value problem It is local in the sense that it is defined only for times in J, and not necessarily for all t ≥ t0. Thus, the problem of proving the existence and uniqueness of integral curves is the same as that of finding solutions to ordinary differential equations/initial value problems and showing that they are unique.
In the above, α′ denotes the derivative of α at time t, the "direction α is pointing" at time t. From a more abstract viewpoint, this is the Fréchet derivative: In the special case that M is some open subset of Rn, this is the familiar derivative where α1,..., αn are the coordinates for αwith respect to the usual coordinate directions. The same thing may be phrased even more abstractly in terms of induced maps. Note that the tangent bundle TJ of J is the trivial bundleJ × R and there is a canonical cross-section ι of this bundle such that ι = 1 for all t ∈ J. The curve α induces a bundle mapα∗ : TJ → TM so that the following diagram commutes: Then the time derivative α′ is the compositionα′ = α∗ o ι, and α′ is its value at some point t ∈ J.
