Local distributional chaos

In discrete dynamical system $(X, f)$ where $X$ is a topological space and $f \in C(X,X)$, three notions of distributional chaos were defined. They were denoted by $DC1, DC2$ and $DC3$. For interval systems such three notions coincide and they will be denoted by DC-chaos. Generally speaking we have $DC1 \subseteq DC2 \subseteq DC3$-chaos. We wonder if it is possible that chaos can concentrate in some points and develop a local idea of the distributional chaos. Answering to this question, in [12] is introduced the new notion of $DCi$-points for $i = 1,2,3$. Such special points are those in which DC-chaos of different types concentrate. Also in [12] it is proved that if $f$ is continuous interval map with positive topological entropy, then there is at least one DC1-point in the system. In this paper it is proved that in the symbolic space $(\Sigma, \sigma) $ where $\sigma$ is the shift map, every point of $\Sigma$ is a DC1-point. This result is necessary to prove one of the main results of the paper. If $h(f) > 0 $ for an interval system, then it has an uncountable set of DC1-points and moreover the set can be chosen perfect. In greater dimensions than one, we deal with triangular systems on $I^{2}$. In this case the relationship between topological entropy and different cases of distributional chaos is not clearly understood and several different results are possible. In the paper we use an example of $F$ given by Kolyada in [9] to prove that the corresponding two dimensional system $(I^{2}, F)$ has positive topological entropy but without containing DC2-points, proving that there is no concentration of DC2-chaos