Difference between revisions of "Whitney decomposition"
(Importing text file) |
(TeX) |
||
Line 1: | Line 1: | ||
− | A continuum is a non-empty compact connected [[Metric space|metric space]]. A hyperspace of a continuum | + | {{TEX|done}} |
+ | A continuum is a non-empty compact connected [[Metric space|metric space]]. A hyperspace of a continuum $X$ is a space whose elements are in a certain class of subsets of $X$. The most common hyperspaces are: | ||
− | + | $2^X$, the set of subsets $A\subset X$ that are closed and non-empty; and | |
− | + | $C(X)$, the set of subsets $A\in2^X$ that are connected. Both sets are considered with the [[Hausdorff metric|Hausdorff metric]]. | |
− | A Whitney mapping for | + | A Whitney mapping for $2^X$ is a [[Continuous function|continuous function]] $\mu$ from $2^X$ to the closed unit interval $[0,1]$ such that $\mu(X)=1$, $\mu(\{x\})=0$ for each point $x\in X$ and, if $A,B\in2^X$ and $A$ is a proper subset of $B$, then $\mu(A)<\mu(B)$. |
− | Every continuum admits Whitney mappings [[#References|[a2]]], Thm. 13.4. These mappings are an important tool in the study of hyperspaces and they represent a way to give a "size" to the elements of | + | Every continuum admits Whitney mappings [[#References|[a2]]], Thm. 13.4. These mappings are an important tool in the study of hyperspaces and they represent a way to give a "size" to the elements of $2^X$. |
− | A Whitney level is a fibre of the restriction to | + | A Whitney level is a fibre of the restriction to $C(X)$ of a Whitney mapping for $2^X$, that is, Whitney levels are sets of the form $\mu^{-1}(t)\cap C(X)$, where $\mu$ is a Whitney mapping for $2^X$ and $0<t<1$. |
− | It is possible to consider the notion of Whitney level for | + | It is possible to consider the notion of Whitney level for $2^X$; these have not been very interesting, mainly because they are not necessarily connected [[#References|[a2]]], Thm. 24.2. |
− | In the case of | + | In the case of $C(X)$, Whitney levels are always compact and connected [[#References|[a2]]], Thm. 19.9, and they have many similarities with the continuum $X$ (see [[#References|[a2]]], Chap. VIII, for these similarities). |
− | Furthermore, given a fixed Whitney mapping | + | Furthermore, given a fixed Whitney mapping $\mu$, the set $\{\mu^{-1}(t)\cap C(X):t\in[0,1]\}$ is a very nice (continuous) decomposition of the hyperspace $C(X)$. A set of this form is called a Whitney decomposition. |
− | A Whitney decomposition can be considered as an element of the hyperspace (of second order) | + | A Whitney decomposition can be considered as an element of the hyperspace (of second order) $C(C(X))$; then it is possible to consider the space of Whitney decompositions, $\operatorname{WD}(X)$. In [[#References|[a1]]] it was proved that for every continuum $X$, $\operatorname{WD}(X)$ is homeomorphic to the Hilbert linear space $l_2$. |
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> A. Illanes, "The space of Whitney decompositions" ''Ann. Inst. Mat. Univ. Nac. Autónoma México'' , '''28''' (1988) pp. 47–61</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A. Illanes, S.B. Nadler Jr., "Hyperspaces, fundamentals and recent advances" , ''Monogr. Textbooks Pure Appl. Math.'' , '''216''' , M. Dekker (1999)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> A. Illanes, "The space of Whitney decompositions" ''Ann. Inst. Mat. Univ. Nac. Autónoma México'' , '''28''' (1988) pp. 47–61</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A. Illanes, S.B. Nadler Jr., "Hyperspaces, fundamentals and recent advances" , ''Monogr. Textbooks Pure Appl. Math.'' , '''216''' , M. Dekker (1999)</TD></TR></table> |
Latest revision as of 15:02, 29 December 2018
A continuum is a non-empty compact connected metric space. A hyperspace of a continuum $X$ is a space whose elements are in a certain class of subsets of $X$. The most common hyperspaces are:
$2^X$, the set of subsets $A\subset X$ that are closed and non-empty; and
$C(X)$, the set of subsets $A\in2^X$ that are connected. Both sets are considered with the Hausdorff metric.
A Whitney mapping for $2^X$ is a continuous function $\mu$ from $2^X$ to the closed unit interval $[0,1]$ such that $\mu(X)=1$, $\mu(\{x\})=0$ for each point $x\in X$ and, if $A,B\in2^X$ and $A$ is a proper subset of $B$, then $\mu(A)<\mu(B)$.
Every continuum admits Whitney mappings [a2], Thm. 13.4. These mappings are an important tool in the study of hyperspaces and they represent a way to give a "size" to the elements of $2^X$.
A Whitney level is a fibre of the restriction to $C(X)$ of a Whitney mapping for $2^X$, that is, Whitney levels are sets of the form $\mu^{-1}(t)\cap C(X)$, where $\mu$ is a Whitney mapping for $2^X$ and $0<t<1$.
It is possible to consider the notion of Whitney level for $2^X$; these have not been very interesting, mainly because they are not necessarily connected [a2], Thm. 24.2.
In the case of $C(X)$, Whitney levels are always compact and connected [a2], Thm. 19.9, and they have many similarities with the continuum $X$ (see [a2], Chap. VIII, for these similarities).
Furthermore, given a fixed Whitney mapping $\mu$, the set $\{\mu^{-1}(t)\cap C(X):t\in[0,1]\}$ is a very nice (continuous) decomposition of the hyperspace $C(X)$. A set of this form is called a Whitney decomposition.
A Whitney decomposition can be considered as an element of the hyperspace (of second order) $C(C(X))$; then it is possible to consider the space of Whitney decompositions, $\operatorname{WD}(X)$. In [a1] it was proved that for every continuum $X$, $\operatorname{WD}(X)$ is homeomorphic to the Hilbert linear space $l_2$.
References
[a1] | A. Illanes, "The space of Whitney decompositions" Ann. Inst. Mat. Univ. Nac. Autónoma México , 28 (1988) pp. 47–61 |
[a2] | A. Illanes, S.B. Nadler Jr., "Hyperspaces, fundamentals and recent advances" , Monogr. Textbooks Pure Appl. Math. , 216 , M. Dekker (1999) |
Whitney decomposition. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Whitney_decomposition&oldid=12899