Centre of a topological dynamical system

(of a flow (continuous-time dynamical system) or of a cascade) with phase space

The largest closed invariant set for which all points are non-wandering (cf. Non-wandering point) under the restriction of the original system to . (Cf. also Topological dynamical system.) The centre is necessarily non-empty if the space is compact (more generally, if there is a semi-trajectory with compact closure). G.D. Birkhoff, who introduced the concept of a centre, used another, but equivalent, definition by means of a certain transfinite process (see [1]–[4]). The number of steps of this process is called the depth of the centre (in fact, there are several "depths" , since this process allows certain modifications). The depth of the centre is not large for flows on compact manifolds of dimension (see [5], [6]) or for cascades obtained by the iteration of a homeomorphism of a circle or of an (even non-invertible) continuous mapping of an interval (see [7]), but it can be an arbitrarily large countable transfinite number even for flows in and on certain open surfaces (see [8]–[10]). In a complete metric space the centre coincides with the closure of the set of points having the property of Poisson stability.

If is compact and is a neighbourhood of the centre, then the trajectory of each point "stays most of the time in U" : The fraction in of those for which tends to 1 as . However, the smallest closed invariant set having this property (the minimal centre of attraction, see [3] and [4]) is, in general, only a part of the centre; in the metrizable case it coincides with the closure of the union of all ergodic sets (cf. Ergodic set).

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