Interior of Simple Closed Contour is Well-Defined

Theorem
Let $C$ be a simple closed contour in the complex plane.

Let $f : \closedint 0 1 \to \R^2$ be a Jordan curve.

Let $\phi : \R^2 \to \C$ be defined by:


 * $\map \phi {x, y} = x + i y$

Let $\Img C = \map \phi {\Img f}$, where $\Img C$ denotes the image of $C$, and $\Img f$ denotes the image of $f$.

Then the interior of $C$:


 * $\Int C = \map \phi {\Int f}$

is well-defined.

Here, $\Int f$ denotes the interior of $f$.

Proof
Let $C$ be defined as a concatenation of a (finite) sequence of directed smooth curves $\sequence {C_1, \ldots, C_n}$.

We show existence of a Jordan curve $f : \closedint 0 1 \to \R^2$ that fulfills the criteria $\map \phi {\Img f} = \Img C$.

Reparameterization of Directed Smooth Curve with Given Domain shows that $C_i$ can be reparameterized by a smooth path:


 * $\gamma_i: \closedint {\dfrac {i - 1} n} {\dfrac i n} \to \C$ for all $i \in \set {1, \ldots, n}$

Define $\gamma: \closedint 0 1 \to \C$ by:


 * $\map \gamma t = \map {\gamma_i} t$ for all $t \in \closedint {\dfrac {i - 1} n} {\dfrac i n}$

Reparameterization of Directed Smooth Curve Preserves Image shows that $\Img \gamma = \Img C$.

Pasting Lemma for Pair of Continuous Mappings on Closed Sets shows that $\gamma$ is continuous.

By definition of simple contour, it follows that:


 * $\map \gamma {t_1} \ne \map \gamma {t_2}$ for all $t_1 \in \hointr 0 1, t_2 \in \hointr 0 1$ with $t_1 \ne t_2$

By definition of closed contour, it follows that:


 * $\map \gamma 0 = \map \gamma 1$

Complex Plane is Homeomorphic to Real Plane shows that $\phi$ is a homeomorphism.

Composite of Continuous Mappings between Metric Spaces is Continuous shows that $\phi^{-1} \circ \gamma : \closedint 0 1 \to \R^2$ is continuous.

As $\phi^{-1}$ is a homeomorphism, it follows by the definition of Jordan curve that $\phi^{-1} \circ \gamma$ is a Jordan curve.

Set $f = \phi^{-1} \circ \gamma$.

We now have $\Img C = \map \phi {\Img f}$.

We show uniqueness of the definition of $\Int C$.

Let $g: \closedint 0 1 \to \R^2$ be a Jordan curve such that $\Img g = \Img f$.

Jordan Curve Theorem shows that the definition of the interior of a Jordan curve only depends on the image of the Jordan curve.

Then:


 * $\Int g = \Int f$