\magnification 2400
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\vsize 9.7 truein
\hoffset -0.45truein
\def\u{\vskip -7pt}
\def\v{\vskip -6pt}
\def\f{\vskip 16pt}



Defn: If $X$ is an ordered set and $a \in X$, then the following are rays in $X$:  

\centerline{$(a, +\infty) = \{x ~|~ x > a\}, ~(-\infty, a) = \{x ~|~ x < a\}$,}

\centerline{$[a, +\infty) = \{x ~|~ x \geq a\}, ~(-\infty, a] = \{x ~|~ x \leq a\}.$}

Lemma:  The collection of all open rays is a subbasis for the order topology.

\vskip 6pt
\vfil
\hrule
\vskip -6pt
\vfil


15:  The Product Topology

Let ${\cal T}_X$ denote the topology on $X$ and ${\cal T}_Y$ denote the topology on $Y$.

Defn:  Let $X$ and $Y$ be topological Spaces.  The {\bf product topology} on $X \times Y$ is the topology having as basis ${\cal B } = \{U \times V ~|~ U \in {\cal T}_X , V \in {\cal T}_Y \}$.

Thm 15.1:  If ${\cal B}_X$ is a basis for the topology of $X$ and  ${\cal B}_Y$ is a basis for the topology of $Y$,  then ${\cal D} = \{ U \times V ~|~ U \in {\cal B}_X , V \in {\cal B}_Y \}$ is a basis for the topology of  $X \times Y$.

Ex. 1:  If $R$ has the standard topology, the product topology on $R \times R$ is the standard topology on $R^2$.

Defn:  Let $\pi_1: X_1 \times X_2 \rightarrow X_1$, $\pi_1(x_1, x_2) = x_1$.
\break
 $\pi_1$ is the projection of $X_1 \times X_2$ onto the first
component.

\f

Note:  If $U \subset X_1$, then $\pi_{1}^{-1}(U) = U \times X_2$.  Thus
if
$U$ is open in $X_1$, then $\pi_{1}^{-1}(U)$ is open in $ X_1 \times
X_2$

\f

Note:  $\pi_{1}^{-1}(U) \cap \pi_{2}^{-1}(V) = U \times V$

\f

Thm 15.2:  The collection \hskip -20pt $${\cal S} = \{\pi_{1}^{-1}(U)
~|~ U
\hbox{ open in}
X
\} \cup \{\pi_{2}^{-1}(V) ~|~ V \hbox{ open in} Y \}$$ is a subbasis
for the
product topology on $X \times Y$.


\f\f
\hrule

HW p. 91:  4, 6, 8

\end

16. The Subspace Topology.

Defn:  Let $(X, {\cal T})$ be a topological space, $Y \subset X$.  
Then the {\bf subspace topology} on $Y$ is the set $${\cal T}_Y = \{U
\cap Y ~|~ U \in {\cal T} \}$$ $(Y, {\cal T}_Y)$ is a {\bf subspace} of
$X$.

Lemma 16.1:  If ${\cal B}$ is a basis for the topology of $X$, then the
set $${\cal B}_Y = \{B \cap Y ~|~ B \in {\cal B} \}$$ is a basis for
the subspace topology on $Y$.

Lemma 16.2:  Let $Y$ be a subspace of $X$.  If $U$ is open in $Y$ and
$Y$ is open in $X$, then $U$ is open in $X$.

Lemma 16.3:  If $A_j$ is a subspace of $X_j$, $j = 1, 2$, then the
product topology on $A_1 \times A_2$ is the same as the topology $A_1
\times A_2$ inherits as a subspace of $X_1 \times X_2$.

Note:  Suppose $Y \subset X$ where $X$ is an ordered set with the order
topology. The order topology on $Y$ need not be the same as the
subspace topology on $Y$

Ex 1:$(0, 1) \cup \{5\}

Defn:  Suppose $Y \subset X$ where $X$ is an ordered set.  $Y$ is {\bf convex}  if for all $a, b \in Y$ such that $a < b$, then $(a, b) \subset Y$

Ex. 1:  $(1, 2) \cup (3, 4) \subset R$.

Ex. 2:  $(1, 2) \cup (3, 4) \subset (1, 2) \cup (3, 9)$.

Lemma 16.4:  Let $X$ is an ordered set with the order topology.  Let $Y$ be a convex subset of $X$.  Then the order topology on $Y$ is the same as the subspace topology on $Y$.

HW p91:  3 (prove your answer).

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17.  Closed Sets and Limit Points

Defn:  The set $A$ is {\bf closed} iff $X - A$ is open.

Thm 17.1:  $X$ be a topological space if and only if the following conditions hold:
\v
(1) $\emptyset$, $X$ are closed.
\v
(2) Arbitrary intersections of closed sets are closed.
\v
(3) Finite unions of closed sets are closed.

Thm 17.2:  Let $Y$ be a subspace of $X$.  Then a set $A$ is closed in $Y$ if and only if it equals the intersection of a closed set of $X$ with $Y$.

Thm 17.3:  Let $Y$ be a subspace of $X$.  If $A$ is closed in $Y$ and $Y$ is closed in $X$, then $A$ is closed in $X$.

Defn:  The {\bf interior} of $A$ = $Int~A$ = $A^0$ = $\cup_{U^open \subset A}U$

Defn:  The {\bf closure} of $A$ = $Cl~A = \overline{A} = \cup_{A \subset F^{closed}} F$

Thm 17.4:  Let $Y$ be a subspace of $X$, $A \subset Y$.  Let $\overline{A}$ denote the closure of $A$ in $X$.  Then the closure of $A$ in $Y$ equals $\overline{A} \cap Y$.

Defn:  $A$ {\bf intersects} $B$ is $A \cap B \not= emptyset$

Thm 17.5:  Let $A$ be a subset of the topological space $X$.

(a) $x \in \overline{A}$ if and only if ($x \in U^{open}$ implies $U
\cap A \not=\emptyset$).

(b) $x \in \overline{A}$ if and only if ($x \in B$ where $B$ is a basis element implies $B \cap A \not=\emptyset$).

neighborhood

Ex

Defn:  $x \in X$ is a {\bf limit point} of $A$ iff $U \cap A \ \{x\} \not=emptyset$ for every open set $U$.

Defn:  $A'$ = the set of all limit points of $A$.

Thm 17.6:  $\overline{A} = A \cup A'$.

Cor 17.7:  $A$ closed if and only if $A' \subset A$.

Defn:  $x_n$ converges to a limit $x$ if for every neighborhood $U$ of $x$, there exists a positive integer $N$ such that $n \geq N$ implies $x_n \in U$.

Note:  limit point of a set is not the same as limit of a sequence.

Defn:  $X$ is {\bf Hausdorff space} if for all $x_1, x_2 \in X$ such that $x_1 \not= x_2$, there exists neighborhoods $U_1$ and $U_2$ of $x_1$ and $x_2$, respectively such that $U_1 \cap U_2 = \emptyset$.

Thm 17.8:  Every finite point set in a Hausdorff space $X$ is closed.

Defn:  $X$ is $T_1$ if every one point set is closed.

Thm 17.9:  Let $X$ by $T_1$, $A \subset X$.  Then $x$ is a limit point of $A$ is and only if every neighborhood of $x$ contains infinitely many points of $A$.

Thm 17.10:  If $X$ is Hausdorff, then a sequence of points of $X$ convereges to at most one point of $X$.  (IFF?)

${1 \over n}$ converges to in the finite complement topology.

Thm 17.11:  If $X$ has the order topology, then $X$ is Hausdorff.  The product of two Hausdorff spaces is Hausdorff.  A subspace of a Hausdorff space is Hausdorff.

17. Continuous Functions

Defn:  $f^{-1}(V) = \{x ~|~ f(x) \in V \}$.

Defn:  $f: X \rightarrow Y$ is continuous iff for every $V$ open in $Y$, $f^{-1}(V)$ is open in $X$. 

Lemma: $f$ continuous if and only if for every basis element $B$, $f^{-1}(B)$ is open in $X$. 

Lemma: $f$ continuous if and only if for every subbasis element $S$, $f^{-1}(S)$ is open in $X$. 

Thm 18.1:  Let $f: X \rightarrow Y$.  Then the following are equivalent:

(1) $f$ is continuous.

(2) For every subset $A$ of $X$, $f(\overline{A}) \subset \overline{f(A)}$.

(3) For every closed set $B$ of $Y$, $f^{-1}(B) is closed in X.


(4) For each $x \in X$ and each neighborhood $V$ of $f(x)$, there is a neighborhood $U$ of $x$ such that $f(U) \subset V$.

Defn:  $f: X \rightarrow Y$ is a homeomorphism iff $f$ is a bijection and both $f$ and $f^{-1}$ is continuous. 

topological property

imbedding

Thm 18.2

(a.) (Constant function)  The constant map $f: X \rightarrow Y$, $f(x) = y_0$ is continuous.

(b.) (Inclusion)  If $A$ is a subspace of $X$, then the inclusion map $f: A \rightarrow X$, $f(a) = a$ is continuous.

(c.) (Composition) If $f: X \rightarrow Y$ and $g: Y \rightarrow Z$ are continuous, then $g \circ f: X \rightarrow Z$ is continuous.

(d.) (Restricting the Domain) If $f: X \rightarrow Y$ is continuous and
if $A$ is a subspace of $X$, then the restricted function $f|_A: A
\rightarrow Y$, $~f|_A(a) = f(a)$ is continuous.

(e.) (Restricting or Expanding the Codomain)  If $f: X \rightarrow Y$ is continuous and if $Z$ is a subspace of $Y$ containing the image set $f(X)$ or if $Y$ is a subspace of $Z$, then $g: X \rightarrow Z$ is continuous.

(f.) (Local formulation of continuity)  If $f: X \rightarrow Y$ and $X = \cup U_\alpha$, $U_\alpha$ open where $f|_{U_\alpha} U_\alpha \rightarrow Y$ is continuous, then $f: X \rightarrow Y$ is continuous.

Thm 18.3 (The pasting lemma)> Let $X = A \cup B$ where $A$, $B$ are
closed in $X$.  Let $f: A \rightarrow Y$ and $g: B \rightarrow Y$ be
continuous.  If $f(x) = g(x)$ for all $x \in A \cap B$, then $h:X
\rightarrow Y$, $h(x) = \cases{f(x) & $x \in A$ \cr g(x) & $x \in B$}
is
continuous.

THm 18.4:  Let $f: A \rightarrow X \times Y$ be given by the equations
$f(a) = (f_1(a), f_2(a))$ where $f_1: A \rightarrow X$, $f_2: A
\rightarrow X$.  Then $f$ is continuous if and only if $f_1$ and $f_2$ are continuous.

19. The Product Topology.

Defn:  Let $J$ be an index set.  Given a set $X$, a {\bf J-tuple} of elements of $X$ is a function ${\bf x}: J \rightarrow X$.  The {\bf $\alpha$th coordinate of x} = $x_\alpha$ = {\bf x}$(\alpha)$



\end

Let $\pi_j: \Pi_{i=0}^n X_i \rightarrow X_j$, $\pi_j(x_1, ..., x_n) = x_j$.
$\pi_j$ is the projection of $\Pi_{i=0}^n X_i $ onto the $j$th component.


Note: