 Research
 Open access
 Published:
On local aspects of sensitivity in topological dynamics
Advances in Difference Equations volumeÂ 2015, ArticleÂ number:Â 280 (2015)
Abstract
In this paper along with the research on weakly mixing sets and transitive sets, we introduce a local aspect of sensitivity in topological dynamics and give the concept of an sset. It is shown that a weakly mixing set is an sset. A transitive set with the set of periodic points being dense is an sset. In particular, a transitive set is an sset for interval maps. Moreover, we discuss ssets for setvalued discrete dynamical systems.
1 Introduction
A topological dynamical system (abbreviated by TDS) is a pair \((X,f)\), where X is a compact metric space with metric d and \(f:X\to X\) is a continuous map. When X is finite, it is a discrete space and there is no nontrivial convergence at all. Hence, we assume that X contains infinitely many points. Let \(\mathbb{N^{+}}\) denote the set of all positive integers and let \(\mathbb{N}=\mathbb{N^{+}}\cup \{0\}\).
Transitivity, weak mixing, and sensitive dependence on initial conditions (see [1â€“4]) are global characteristics of topological dynamical systems. Let \((X,f)\) be a TDS, \((X,f)\) is (topologically) transitive if for any nonempty open subsets U and V of X there exists an \(n\in\mathbb{N}\) such that \(f^{n}(U)\cap V\neq\emptyset\). \((X,f)\) is (topologically) mixing if for any nonempty open subsets U and V of X, there exists an \(N\in\mathbb{N}\) such that \(f^{n}(U)\cap V\neq\emptyset\) for all \(n\in\mathbb{N}\) with \(n\geq N\). \((X,f)\) is (topologically) weakly mixing if for any nonempty open subsets \(U_{1}\), \(U_{2}\), \(V_{1}\), and \(V_{2}\) of X, there exists an \(n\in\mathbb{N}\) such that \(f^{n}(U_{1})\cap V_{1}\neq\emptyset\) and \(f^{n}(U_{2})\cap V_{2}\neq\emptyset\). It follows from these definitions that mixing implies weak mixing, which in turn implies transitivity. A map f is said to have sensitive dependence on initial conditions if there is a constant \(\delta>0\) such that for any nonempty open set U of X, there exist points \(x,y\in U\) such that \(d(f^{n}(x),f^{n}(y))> \delta\) for \(n\in\mathbb{N^{+}}\).
In [5], Blanchard introduced overall properties and partial properties. For example, sensitive dependence on initial conditions, Devaney chaos (see [6]), weak mixing, mixing and more belong to overall properties; LiYorke chaos (see [7]) and positive entropy (see [1, 8]) belong to partial properties. Weak mixing is an overall property, it is stable under semiconjugate maps and implies LiYorke chaos. We find that a weakly mixing system always contains a dense uncountable scrambled set (see [9]). In [10], Blanchard and Huang introduced the concepts of a weakly mixing set, derived from a result given by Xiong and Yang [11] and showed â€˜partial weak mixing implies LiYorke chaosâ€™ and â€˜LiYorke chaos cannot imply partial weak mixingâ€™.
Motivated by the idea of Blanchard and Huangâ€™s notion of a â€˜weakly mixing subsetâ€™, Oprocha and Zhang [12] extended the notion of a weakly mixing set and gave the concept of a transitive set and discussed its basic properties. In this paper we give the concept of â€˜ssetâ€™ for topological dynamical systems and investigate the relationship among transitive subsets, weakly mixing sets, and ssets. We find that a TDS to have a weakly mixing set implies it has an sset, and if periodic points are dense in the transitive set, then the transitive set is an sset. In particular, a transitive set is an sset for interval maps. The properties of transitivity, weak mixing, and sensitivity on initial conditions for a setvalued discrete dynamical system were discussed (see [13â€“18]). Also, we continue to discuss ssets for setvalued discrete dynamical systems and investigate the relationship between a setvalued discrete system and an original system on an sset. More precisely, a setvalued discrete system has an sset, which implies that an original system has an sset.
2 Preliminaries
A TDS \((X,f)\) is point transitive if there exists a point \(x_{0}\in X\) with dense orbit i.e., \(\overline{\operatorname{orb}(x_{0})}=X\). Such a point \(x_{0}\) is called a transitive point of \((X,f)\). In general, transitive and point transitive are independent (see [2]). A TDS \((X,f)\) is minimal if \(\overline{\operatorname{orb}(x,f)}=X\) for every \(x\in X\), i.e., every point is transitive point. A point x is called minimal if the subsystem \((\overline{\operatorname{orb}(x,f)},f)\) is minimal. Denote by \(P(f)\) the set of all periodic points.
A LiYorke or scrambled pair \((x,y)\) of \((X,f)\) is a pair of points of X such that

(1)
\(\lim _{n\to\infty}\inf d(f^{n}(x),f^{n}(y))=0\), and

(2)
\(\lim _{n\to\infty}\sup d(f^{n}(x),f^{n}(y))>0\).
A set \(S\subseteq X\) is said to be a scrambled set if for all \(x,y\in S\), \(x\neq y\), the \((x,y)\) is a scrambled pair. A TDS \((X,f)\) is called LiYorke chaotic if it contains an uncountable scrambled set.
A map f is said to be Devaney chaotic if f satisfies the following conditions:

(1)
f is transitive,

(2)
f is periodically dense; i.e., the set of periodic points of f is dense in X, and

(3)
f is sensitive dependent on initial conditions.
Definition 2.1
[10]
Let \((X,f)\) be a TDS and A be a closed subset of X with at least two elements. A is said to be weakly mixing if for any \(k\in\mathbb{N}\), any choice of nonempty open subsets \(V_{1},V_{2},\ldots,V_{k}\) of A and nonempty open subsets \(U_{1},U_{2},\ldots,U_{k}\) of X with \(A\cap U_{i}\neq\emptyset\), \(i=1,2,\ldots,k\), there exists an \(m\in\mathbb{N}\) such that \(f^{m}(V_{i})\cap U_{i}\neq\emptyset\) for \(1\leq i\leq k\). \((X,f)\) is called partial weak mixing if X contains a weakly mixing subset.
Definition 2.2
[12]
Let \((X,f)\) be a TDS and A be a nonempty subset of X. A is called a transitive set of \((X,f)\) if, for any choice of nonempty open subset \(V^{A}\) of A and nonempty open subset U of X with \(A\cap U\neq\emptyset\), there exists an \(n\in\mathbb{N}\) such that \(f^{n}(V^{A})\cap U\neq\emptyset\).
Remark 2.1

(1)
\((X,f)\) is topologically transitive if and only if X is a transitive set of \((X,f)\).

(2)
By [12], A is a transitive set if and only if AÌ… is a transitive set, where AÌ… denotes the closure of A.
According to the definitions of transitive set and weakly mixing subset, we have the following results.
 Result 1.:

If A is a weakly mixing set of \((X,f)\), then A is a transitive set of \((X,f)\).
 Result 2.:

If \(a\in X\) is a transitive point of \((X,f)\), then \(\{a\}\) is a transitive set of \((X,f)\).
 Result 3.:

If \(A=\operatorname{orb}(x,f)\) is a periodic orbit of \((X,f)\) for some \(x\in X\), then A is a transitive set of \((X,f)\).
Definition 2.3
A nonempty subset A is called an sset of \((X,f)\) if there exists a \(\delta>0\) such that for any \(x\in A\) and \(\varepsilon>0\), there exist a \(y\in B(x,\varepsilon)\cap A\) and an \(n\in\mathbb{N^{+}}\) satisfying \(d(f^{n}(x),f^{n}(y))>\delta\).
Remark 2.2
The sset is dense in itself, i.e., it contains no isolated points. X is an sset of \((X,f)\) if and only if \((X,f)\) is sensitive dependent on initial conditions.
Let \((X,f)\) and \((Y,g)\) be two TDSs. Then \((X,f)\) is an extension of \((Y,g)\), or \((Y,g)\) is a factor of \((X,f)\) if there exists a surjective continuous map \(h: X\to Y\) (called a factor map) such that \(h\circ f(x)=g\circ h(x)\) for every \(x\in X\). If further h is a homeomorphism, then \((X,f)\) and \((Y,g)\) are said to be topologically conjugate and the homeomorphism h is called a conjugated map.
Theorem 2.1
Let A be a weakly mixing set of \((X,f)\). Then A is an sset of \((X,f)\).
Proof
Let A be a weakly mixing set of \((X,f)\). Then A contains at least two points. Pick up two distinct points \(x_{1},x_{2}\in A\) and set \(\delta=\frac{1}{4}d(x_{1},x_{2})>0\). For any \(x\in A\) and \(\varepsilon>0\), we see that \(B(x,\varepsilon)\) is a nonempty open subset of X.
We consider an open subset \(B(x,\varepsilon)\cap A\) of A and two open subsets \(B(x_{1},\delta)\), \(B(x_{2},\delta)\) of X. Since A is a weakly mixing set and \(B(x_{1},\delta)\cap A\neq\emptyset\), \(B(x_{2},\delta)\cap A\neq\emptyset\), there exists an \(n\in\mathbb{N}\) such that \(f^{n}(B(x,\varepsilon)\cap A)\cap B(x_{1},\delta)\neq\emptyset\) and \(f^{n}(B(x,\varepsilon)\cap A)\cap B(x_{2},\delta)\neq\emptyset\). Furthermore, there exist \(y_{1},y_{2}\in B(x,\varepsilon)\cap A\) such that \(f^{n}(y_{1})\in B(x_{1},\delta)\) and \(f^{n}(y_{2})\in B(x_{2},\delta)\). Moreover,
Therefore, either \(d(f^{n}(x),f^{n}(y_{1}))>\delta\) or \(d(f^{n}(x),f^{n}(y_{2}))>\delta\). This shows that A is an sset of \((X,f)\).â€ƒâ–¡
3 Characterizing ssets
In this section, we discuss the properties of ssets of \((X,f)\). For a TDS \((X,f)\) and two nonempty subsets \(U,V\subseteq X\), we use the following notation:
Lemma 3.1
Let A be an infinite subset of X and \(P(f)\) be dense in A. Then \(P(f)\cap A\) is infinite.
Proof
Suppose that \(P(f)\cap A\) is finite and let \(\operatorname{card}(P(f)\cap A)=n\), where card represents the cardinality of a set. Since A is an infinite subset of X, there exists a pairwise disjoint open set \(V_{i}^{A}\) of A for \(i=1,2,\ldots,n+1\), i.e., \(V_{i}^{A}\cap V_{j}^{A}=\emptyset\) for \(i,j\in\{1,2,\ldots ,n+1\}\) and \(i\neq j\). Moreover, \(P(f)\cap A\) is dense in A, which implies \(\operatorname{card}(P(f)\cap A)\geq n+1\). This is a contradiction. Therefore, \(P(f)\cap A\) is infinite.â€ƒâ–¡
Theorem 3.1
Let \((X,f)\) be a TDS and A be an infinite subset of X. If A is a transitive set of \((X,f)\) and \(P(f)\) is dense in A, then A is an sset of \((X,f)\).
Proof
We first prove that there exists \(\delta_{0}>0\) such that, for any \(x\in A\), there exists \(q\in P(f)\cap A\) satisfying
Indeed, by LemmaÂ 3.1, \(P(f)\cap A\) is an infinite set. Hence, we pick two different points \(q_{1},q_{2}\in P(f)\cap A\) such that \(\operatorname{orb}(q_{1})\cap \operatorname{orb}(q_{2})=\emptyset\). Let
Then, for any \(x\in A\), we have
If (3.2) is false, then
Hence, by the triangle inequality, we have
This is a contradiction by (3.1).
Take \(\delta=\frac{\delta_{0}}{8}\). For any \(x\in A\) and \(\varepsilon>0\), without loss of generality, let \(\varepsilon<\delta\). Since \(P(f)\) is dense in A, we have \(P(A)\cap(B(x,\varepsilon)\cap A)\neq\emptyset\). Furthermore, we can take \(p\in B(x,\varepsilon)\cap A\) and let \(f^{n}(p)=p\). Since \(x\in A\), there exists \(q\in P(f)\cap A\) such that
Let \(U=\bigcap _{i=1}^{n}f^{i}(B(f^{i}(q),\delta))\). Since \(q\in U\), we have \(q\in U\cap A\), which implies \(U\cap A\neq\emptyset\). Moreover, A is a transitive set of \((X,f)\), thus there exists a \(k\in\mathbb{N^{+}}\) such that \(B(x,\varepsilon)\cap A\cap f^{k}(U)\neq\emptyset\). Take \(y\in B(x,\varepsilon)\cap A\cap f^{k}(U)\). Then \(f^{k}(y)\in U\). Let \(j=[\frac{k}{n}+1]\). Then \(1\leq njk\leq n\). Furthermore, we have
Since \(f^{n}(p)=p\), we have \(f^{nj}(p)=p\). Hence, by the triangle inequality,
As \(p\in B(x,\delta)\cap A\) and \(f^{nj}(y)\in B(f^{njk}(q),\delta)\), so
Again, by the triangle inequality, we have
for some \(p\in B(x,\varepsilon)\cap A\) and some \(y\in B(x,\varepsilon)\cap A\). Therefore, A is an sset of \((X,f)\).
By [19], if X is a nondegenerate compact interval, \(f:X\to X\) is a continuous map and f is transitive, then \(P(f)\) is dense in X. We prove that if X is a nondegenerate compact interval, A is a nondegenerate closed interval, and A is a transitive set of \((X,f)\), then \(P(f)\) is dense in A.â€ƒâ–¡
Lemma 3.2
[19]
Suppose that I is a nondegenerate interval and \(f:I\to I\) is a continuous map. If \(J\subseteq I\) is an interval which contains no periodic points of f and z, \(f^{m}(z)\) and \(f^{n}(z)\in J\) with \(0< m< n\), then either \(z< f^{m}(z)< f^{n}(z)\) or \(z>f^{m}(z)>f^{n}(z)\).
Theorem 3.2
Let I be a nondegenerate interval and \(f:I\to I\) be a continuous map. If \(J\subseteq I\) is a nondegenerate closed interval and J is a transitive set of \((I,f)\), then \(P(f)\) is dense in J.
Proof
Suppose that \(P(f)\) is not dense in J. Then there exists a nonempty open set \(J_{1}\) of J containing no periodic points, i.e., \(P(f)\cap J_{1}=\emptyset\). Without loss of generality, let \(J_{1}\) be an open interval of I and \(J_{1}\subseteq J\). Take an \(x\in J_{1}\) which is not an endpoint of \(J_{1}\), an open neighborhood \(U\subsetneq J_{1}\) of x and an open interval \(E\subseteq J_{1}\setminus U\).
We consider open neighborhood U of \(J_{1}\) and open interval E with \(J_{1}\cap E\neq\emptyset\). Since J is a transitive set of \((I,f)\), there exists an \(m\in\mathbb{N}\) such that \(f^{m}(U)\cap E\neq\emptyset\). Furthermore, there exists a \(y\in U\subseteq J_{1}\) such that \(f^{m}(y)\in E\subseteq J_{1}\). Moreover, \(P(f)\cap J_{1}=\emptyset\), it means that \(y\neq f^{m}(y)\). Since I is a Hausdorff space and f is continuous, there exists an open neighborhood V of y such that \(f^{m}(V)\cap V=\emptyset\). Hence, we can take an open interval \(J_{2}\) of I such that \(J_{2}\subseteq J_{1}\) and \(y\in J_{2}\subseteq V\), thus \(f^{m}(J_{2})\cap J_{2}=\emptyset\). Since \(J_{2}\) is an open interval of I and \(J_{2}\subseteq J_{1}\) and J is a transitive set, there exist \(n>m\) and \(z\in U\) such that \(f^{n}(z)\in J_{2}\). Furthermore, we have \(0< m< n\) and \(z, f^{n}(z)\in J_{2}\) while \(f^{m}(z)\notin J_{2}\). This is a contradiction by LemmaÂ 3.2. Therefore, \(P(f)\) is dense in J.â€ƒâ–¡
Example 3.1
We have the tent map (see Figures 1 and 2)
which is called Devaney chaos on \(I=[0,1]\) by [6]. We will prove that \([\frac{1}{4},\frac{3}{4}]\) is a transitive set of \((I,f)\).
Let \(S(f^{k})\) denote the set of extreme value points of \(f^{k}\) for every \(k\in\mathbb{N^{+}}\). Then \(S(f^{k})=\{\frac{1}{2^{k}},\frac{2}{2^{k}},\ldots,\frac{2^{k}1}{2^{k}}\}\). Since \(S(f)=\{\frac{1}{2}\}\), \(f(\frac{1}{2})=1\), \(f(0)=0\), and \(f(1)=0\), we have
Let \(I_{k}^{j}=[\frac{j}{2^{k}},\frac{j+1}{2^{k}}]\) for \(0\leq j\leq2^{k}1\). Then \(f^{k}(I_{k}^{j})=[0,1]\). For any nonempty open set U of \([\frac{1}{4},\frac{3}{4}]\), without loss of generality, we take \(U=(x_{0}\varepsilon,x_{0}+\varepsilon)\) for a given \(\varepsilon>0\) and \(x_{0}\in \operatorname{int}[\frac{1}{4},\frac{3}{4}]\), where \(\operatorname{int}[\frac{1}{4},\frac{3}{4}]\) denotes the interior of \([\frac{1}{4},\frac{3}{4}]\). When \(l\in\mathbb{N}\) and \(l>\log_{2}\frac{1}{\varepsilon}\), there exists j, \(j\in\mathbb{N}\) and \(0\le j\le2^{l}1\), such that \(I_{l}^{j}\subseteq U\). Furthermore, we have \(f^{l}(U)=[0,1]\). Thus, for any nonempty open set U of \([\frac{1}{4},\frac{3}{4}]\) and nonempty open set V of \([0,1]\) with \(V\cap[\frac{1}{4},\frac{3}{4}]\neq\emptyset\), there exists a \(k\in\mathbb{N}\) such that \(f^{k}(U)\cap V\neq\emptyset\). This shows that \([\frac{1}{4},\frac{3}{4}]\) is a transitive set of \((I,f)\). Since \(P(f)\) is dense in I, \(P(f)\) is also dense in \([\frac{1}{4},\frac{3}{4}]\). By TheoremÂ 3.2, \([\frac{1}{4},\frac{3}{4}]\) is an sset of \((I,f)\).
4 ssets for setvalued discrete dynamical systems
The distance from a point x to a nonempty set A in X is defined by
Let \(\kappa(X)\) be the family of all nonempty compact subsets of X. The Hausdorff metric on \(\kappa(X)\) is defined by
It follows from Michael [20] and Engelking [21] that \(\kappa(X)\) is a compact metric space. The Vietoris topology \(\tau_{\upsilon}\) on \(\kappa(X)\) is generated by the base
where \(U_{1},U_{2},\ldots,U_{n}\) are open subsets of X. Let fÌ„ be the induced setvalued map defined by
Then fÌ„ is well defined. \((\kappa(X),\bar{f})\) is called a setvalued discrete dynamical system.
Let X be a \(T_{1}\) space, that is, a single point set that is closed. Then \(\kappa(A)=\{F\in\kappa(X): F\subseteq A\}\) is a closed subset of \(\kappa(X)\) for any nonempty closed subset A of X (see [20]).
Theorem 4.1
Let A be a nonempty closed subset of X. If \(P(f)\) is dense in A, then \(P(\bar{f})\) is dense in \(\kappa(A)\).
Proof
Let \({\mathcal{V}}^{\kappa(A)}\) be a nonempty open subset of \(\kappa(A)\). Then there exists an open set \({\mathcal{V}}\) of \(\kappa (X)\) such that \({\mathcal{V}}^{\kappa(A)}={\mathcal{V}}\cap\kappa(A)\). Without loss of generality, let \({\mathcal{V}}=\nu(V_{1},V_{2},\ldots,V_{m})\). Take \(F\in{\mathcal{V}}\cap\kappa(A)\). Then we have \(F\subseteq A\), \(F\subseteq\bigcup _{i=1}^{m} V_{i}\) and \(F\cap V_{i}\neq\emptyset\) for each \(i=1,2,\ldots,m\). Hence, \(V_{i}\cap A\neq\emptyset\) for each \(i=1,2,\ldots,m\). Since \(P(f)\) is dense in A, it follows that \(P(f)\cap(V_{i}\cap A)\neq\emptyset\) for each \(i=1,2,\ldots,m\). Furthermore, there exist \(y_{i}\in P(f)\cap(V_{i}\cap A)\) and \(n_{i}\in\mathbb{N^{+}}\) such that \(f^{n_{i}}(y_{i})=y_{i}\) for each \(i=1,2,\ldots,m\). Let \(G=\{y_{1},y_{2},\ldots,y_{m}\}\). Then \(G\in {\mathcal{V}}\) and \(G\in\kappa(A)\), which implies \(G\in {\mathcal{V}}^{\kappa(A)}\). Moreover, \(f^{n_{1}n_{2}\cdots n_{m}}(y_{i})=y_{i}\) for each \(i=1,2,\ldots,m\). Therefore, \((\bar{f})^{n_{1}n_{2}\cdots n_{m}}(G)=f^{n_{1}n_{2}\cdots n_{m}}(G)=G\), it means that \(P(\bar{f})\cap {\mathcal{V}}^{\kappa(A)}\neq\emptyset\). This shows that \(P(\bar{f})\) is dense in \(\kappa(A)\).â€ƒâ–¡
Theorem 4.2
Let A be a nonempty closed subset of X. If \(\kappa(A)\) is a sensitive set of \((\kappa(X),\bar{f})\), then A is an sset of \((X,f)\).
Proof
Since \(\kappa(A)\) is an sset of \((\kappa(X),\bar{f})\), there exists a constant \(\delta>0\) such that \(K\in\kappa(A)\) and every \(\varepsilon>0\) there exist \(G\in B(K,\varepsilon)\cap\kappa(A)\) and \(n\in\mathbb{N^{+}}\) such that \(d_{H}((\bar{f})^{n}(K),(\bar{f})^{n}(G))>\delta\).
Let \(x\in A\) and \(\varepsilon>0\). Take \(K=\{x\}\in\kappa(A)\). Then there exist \(G\in B(\{x\},\varepsilon)\cap\kappa(A)\) and \(n\in\mathbb{N^{+}}\) such that
Since \(d_{H}(f^{n}(\{x\}),f^{n}(G))=\sup _{y\in G}d(f^{n}(x),f^{n}(y))\), G is a compact subset of X and \(f: X\to X\) is a continuous map, there exists \(y_{0}\in G\) such that
Moreover, \(G\in B(\{x\},\varepsilon)\cap\kappa(A)\) implies \(G\subseteq B(x,\varepsilon)\) and \(G\subseteq A\), consequently, \(y_{0}\in B(x,\varepsilon)\cap A\). This shows that A is an sset of \((X,f)\).â€ƒâ–¡
References
Block, LS, Coppel, WA: Dynamics in One Dimension. Lecture Notes in Mathematics, vol.Â 1513. Springer, Berlin (1992)
Kolyada, S, Snoha, L: Some aspects of topological transitivity  a survey. Grazer Math. Ber. 334, 335 (1997)
Robinson, C: Dynamical Systems: Stability, Symbolic Dynamics, and Chaos, 2nd edn. CRC Press, Boca Raton (1999)
Walters, P: An Introduction to Ergodic Theory. Texts in Math., vol.Â 79. Springer, New York (1982)
Blanchard, F: Topological chaos: what may this mean? J. Differ. Equ. Appl. 15, 2346 (2009)
Devaney, RL: An Introduction to Chaotic Dynamical Systems. AddisonWesley, Redwood City (1989)
Li, TY, Yorke, J: Period three implies chaos. Am. Math. Mon. 82, 985992 (1975)
Ruette, S: Chaos for continuous interval maps: a survey of relationship between the various sorts of chaos. http://www.math.upsud.fr/~ruette/
Iwanik, A: Independence and scrambled sets for chaotic mapping. In: The Mathematical Heritage of C.F. Gauss, pp.Â 372378. World Scientific, River Edge (1991)
Blanchard, F, Huang, W: Entropy sets, weakly mixing sets and entropy capacity. Discrete Contin. Dyn. Syst. 20, 275311 (2008)
Xiong, J, Yang, Z: Chaos Caused by a Topologically Mixing Map. Advanced Series in Dynamical Systems, vol.Â 9, pp.Â 550572. World Scientific, Singapore (1991)
Oprocha, P, Zhang, G: On local aspects of topological weak mixing in dimension one and beyond. Stud. Math. 202, 261288 (2011)
Banks, J: Chaos for induced hyperspace maps. Chaos Solitons Fractals 25, 681685 (2005)
Fedeli, A: On chaotic setvalued discrete dynamical systems. Chaos Solitons Fractals 23, 13811384 (2005)
Peris, A: Setvalued discrete chaos. Chaos Solitons Fractals 26, 1923 (2005)
RomanFlores, H: A note on transitivity in setvalued discrete systems. Chaos Solitons Fractals 71, 99104 (2003)
Wang, Y, Wei, G: Characterizing mixing, weak mixing and transitivity of induced hyperspace dynamical systems. Topol. Appl. 155, 5668 (2007)
Wang, Y, Wei, G, Campbell, H: Sensitive dependence on initial conditions between dynamical systems and their induced hyperspace dynamical systems. Topol. Appl. 156, 803811 (2009)
Vellekoop, M, Bergund, R: On interval, transitivity = chaos. Am. Math. Mon. 101, 353355 (1994)
Michael, E: Topologies on spaces of subsets. Trans. Am. Math. Soc. 71, 152182 (1951)
Engelking, R: General Topology. PWN, Warsaw (1977)
Acknowledgements
The work was supported by the National Natural Science Foundation of China (11401363) and the Education Foundation of Henan Province (13A110832, 14B110006), P.R. China. The authors would like to thank the referees for many valuable and constructive comments and suggestions for improving this paper.
Author information
Authors and Affiliations
Corresponding author
Additional information
Competing interests
The authors declare that they have no competing interests.
Authorsâ€™ contributions
LL and HL carried out the study of stronger forms of sensitivity for inverse limit dynamical systems and drafted the manuscript. JP helped to draft the manuscript. All authors read and approved the final manuscript.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Liu, L., Li, H. & Pang, J. On local aspects of sensitivity in topological dynamics. Adv Differ Equ 2015, 280 (2015). https://doi.org/10.1186/s1366201506055
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s1366201506055