Andronov–Pontryagin criterion

Statement

A dynamical system

: \dot{x} = v(x),

where v is a C^{1}-vector field on the plane, x \in \mathbb{R}^{2}, is orbitally topologically stable if and only if the following two conditions hold:

1. All equilibrium points and periodic orbits are hyperbolic.
2. There are no saddle connections.

The same statement holds if the vector field v is defined on the unit disk and is transversal to the boundary.

Clarifications

Orbital topological stability of a dynamical system means that for any sufficiently small perturbation (in the C1-metric), there exists a homeomorphism close to the identity map which transforms the orbits of the original dynamical system to the orbits of the perturbed system (cf structural stability).

The first condition of the theorem is known as global hyperbolicity. A zero of a vector field v, i.e. a point x0 where v(x0)=0, is said to be hyperbolic if none of the eigenvalues of the linearization of v at x0 is purely imaginary. A periodic orbit of a flow is said to be hyperbolic if none of the eigenvalues of the Poincaré return map at a point on the orbit has absolute value one.

Finally, saddle connection refers to a situation where an orbit from one saddle point enters the same or another saddle point, i.e. the unstable and stable separatrices are connected (cf homoclinic orbit and heteroclinic orbit).

References

• Cited in .
• . See Theorem 2.5.