User:Anghel/Sandbox

Theorem
Let $\closedint a b$ denote the closed real interval between $a \in \R, b \in \R: a \le b$.

Let $\gamma: \closedint a b \to \R^2$ be a Jordan curve.

Let the interior of $\gamma$ be denoted $\Int \gamma$.

Let the image of $\gamma$ be denoted $\Img \gamma$.

Let $\sigma: \closedint c d \to \R^2$ be a Jordan arc such that:


 * $\map \sigma c, \map \sigma d \in \Img \gamma$

and:


 * $\forall t \in \openint c d: \map \sigma t \in \Int \gamma$

Let $t_1 = \map {\gamma^{-1} } {\map \sigma c}$.

Let $t_2 = \map {\gamma^{-1} } {\map \sigma d}$.

Let $t_1 < t_2$.

Define:
 * $-\sigma: \closedint c d \to \Img \sigma$ by $-\map \sigma t = \map \sigma {c + d - t}$

Let $*$ denote concatenation of paths.

Let $\gamma \restriction_{\closedint a {t_1} }$ denote the restriction of $\gamma$ to $\closedint a {t_1}$.

Define:
 * $\gamma_1 = \gamma \restriction_{\closedint a {t_1} } * \sigma * \gamma {\restriction_{\closedint {t_2} b} }$

Define:
 * $\gamma_2 = \gamma \restriction_{\closedint {t_1} {t_2} } * \paren {-\sigma}$

Then $\gamma_1$ and $\gamma_2$ are Jordan curves such that:


 * $\Int {\gamma_1} \cup \Int {\gamma_2} \cup \paren { \Img \sigma \setminus \set { \map \sigma c, \map \sigma d } } = \Int \gamma$

Proof
Let $\closedint {a_1}{b_1}$ denote the domain of $\gamma_1$, and $\closedint {a_2}{b_2}$ denote the domain of $\gamma_2$.

As:
 * $\Int \gamma$ and $\Img \gamma$ are disjoint by the Jordan Curve Theorem

and:
 * $\map \sigma {\openint c d} \subseteq \Int \gamma$

it follows that:
 * $\Img \gamma \cap \Img \sigma = \set {\map \sigma c, \map \sigma d}$.

As $\gamma$ is a Jordan curve, it follows that $\gamma {\restriction_{\closedint a {t_1} } }$ and $\gamma {\restriction_{\closedint {t_2} b} }$ intersect only in $\map \gamma a$.

It follows that:


 * $\map { \gamma_1 }{t_1} \ne \map { \gamma_1 }{t_2}$ for all $t_1 ,t_2 \in \hointr {a_1}{b_1}$ with $t_1 \ne t_2$

As the initial point of $\gamma_1$ is $\map \gamma a$, and the final point of $\gamma_1$ is $\map \gamma b = \map \gamma a$, it follows that $\gamma_1$ is a Jordan curve.

As $\Img {-\sigma} = \Img \sigma$, it follows that:


 * $\map { \gamma_2 }{t_1} \ne \map { \gamma_2 }{t_2}$ for all $t_1 ,t_2 \in \hointr {a_2}{b_2}$ with $t_1 \ne t_2$

As $\map \gamma {t_1} = \map \sigma c = -\map \sigma d$, it follows that $\gamma_2$ is a Jordan curve.

Denote the exterior of $\gamma$ as $\Ext \gamma$.

Let $q_0 \in \Ext \gamma$ be determined.

By the Jordan Curve Theorem, $\Ext \gamma$ is unbounded.

Hence for all $N \in \N$ there exists $q \in \Ext \gamma$ such that:


 * $\map d {\mathbf 0, q} > N$

where $d$ denotes the Euclidean metric on $\R^2$.

The Jordan Curve Theorem also shows that $\Ext \gamma$ is open and connected.

From Connected Open Subset of Euclidean Space is Path-Connected, it follows that $\Ext \gamma$ is path-connected.

Then, there exists a path $\rho$ in $\Ext \gamma$ from $q$ to $q_0$.

We have:


 * $\Img {\gamma_1} \subseteq \Int \gamma \cup \Img \gamma$

This is disjoint with $\Ext \gamma$

Thus it follows that $\rho$ is a path in either $\Ext {\gamma_1}$ or $\Int {\gamma_1}$.

We have that $\map d {\mathbf 0, q}$ can be arbitrary large.

Also, $\Int {\gamma_1}$ is bounded.

So follows that $\rho$ is a path in $\Ext {\gamma_1}$.

In particular:
 * $q \in \Ext {\gamma_1}$

Therefore:
 * $\Ext \gamma \subseteq \Ext {\gamma_1}$

Let $q_1 \in \Int {\gamma_1}$.

Then:
 * $q_1 \notin \Ext \gamma$

as $\Int {\gamma_1}$ and $\Ext {\gamma_1}$ are disjoint.

It follows that:
 * $q_1 \in \Int {\gamma_1}$

Therefore:
 * $\Int {\gamma_1} \subseteq \Int \gamma$

Similarly, it follows that:
 * $\Int {\gamma_2} \subseteq \Int \gamma$

It follows from the definition of $\sigma$ that:
 * $\Img \sigma \setminus \set { \map \sigma c, \map \sigma d } \subseteq \Int \gamma$

and thus:
 * $\Int {\gamma_1} \cup \Int {\gamma_2} \cup \paren { \Img \sigma \setminus \set { \map \sigma c, \map \sigma d } } \subseteq \Int \gamma$

Next, we show that $\Ext {\gamma_1 } \cap \Ext {\gamma_2} = \Ext \gamma$.

Let $q \in \Ext {\gamma_1 } \cap \Ext {\gamma_2}$.

Let $\rho$ be a path in $\Ext {\gamma_1}$ from $q$ to $q_0$.

If $\rho$ does not intersect $\Img {\gamma_2}$, then $\rho$ is a path in $\Ext {\gamma_2}$.

It follows by definition of path-connected set that $q \in \Ext {\gamma_1 } \cap \Ext {\gamma_2}$.

Instead, suppose that $\rho$ first intersects $\Img {\gamma_2}$ in $\map {\gamma_2} t$ for some $t \in \R$.

Suppose $\map {\gamma_2} t = \map \sigma s$ for some $s \in \openint c d$.

From Closed Real Interval is Compact and Continuous Image of Compact Space is Compact, it follows that $\Img \gamma$ is compact.

From Distance between Disjoint Compact Set and Closed Set in Metric Space is Positive, it follows that there exists $r \in \R_{>0}$ such the open ball $\map {B_r}{ \map \sigma s }$ is disjoint with $\Img \gamma$.

As $\map \sigma s \in \Int \gamma$, it follows that $\map {B_r}{ \map \sigma s } \subseteq \Int \gamma$.

Let $q_2 \in \map {B_r}{ \map \sigma s }$ such that $\rho$ reaches $q_2$ before $\rho$ intersects $\Img \gamma_2$.

Then $q_2 \in \Ext {\gamma_1 } \cap \Ext {\gamma_2}$.

It follows that there exists a