Dynamics of continuous maps induced on the space of probability measures

Abstract

For a continuous self-map f on a compact interval I and the induced map f on the space M(I) of probability measures, we obtain a sharp condition to guarantee that (I,f) is transitive if and only if (M(I), f) is transitive. We also show that the sensitivity of (I,f) is equivalent to that of (M(I), f). We prove that (M(I), f) must have infinite topological entropy for any transitive system (I,f), while there exists a transitive non-autonomous system (I,f0,∞) such that (M(I), f0,∞) has zero topological entropy, where f0,∞=\fn\n=0∞ is a sequence of continuous self-maps on I. For a continuous self-map f on a general compact metric space X, we show that chain transitivity of (X, f) implies chain mixing of (M(X), f), and we provide two counterexamples to demonstrate that the converse is not true. We confirm that shadowing of (X,f) is not inherited by (M(X), f) in general. For a non-autonomous system (X,f0,∞), we prove that if (M(X),f0,∞) is weak mixing of order n, then so is (X,f0,∞) for any n≥2; while there exists (X,f0,∞) such that it is weak mixing of order 2 but (M (X),f0,∞) is not. We then prove that Li-Yorke chaos (resp., distributional chaos) of (X,f0,∞) carries over to (M(X), f0,∞), and give an example to show that (X,f) and (M(X), f) may have no Li-Yorke pair simultaneously. We also prove that if fn is surjective for all n≥ 0, then chain mixing of (M(X), f0,∞) always holds true, and shadowing of (M(X), f0,∞) implies mixing of (X, f0,∞).