Jordan Polygon Interior and Exterior Criterion

Theorem
Let $P$ be a polygon embedded in $\R^2$.

Let $q \in \R^2 \setminus \partial P$, where $\partial P$ denotes the boundary of $P$.

Let $\mathbf v \in \R^2 \setminus \set \bszero$ be a non-zero vector.

Let $\LL = \set {q + s \mathbf v: s \in \R_{\ge 0} }$ be a ray with start point $q$.

Let $\map N q \in \N$ be the number of crossings between $\LL$ and $\partial P$.

Then:


 * $(1): \quad$ $q \in \Int P$, $\map N q \equiv 1 \pmod 2$


 * $(2): \quad$ $q \in \Ext P$, $\map N q \equiv 0 \pmod 2$

Here, $\Int P$ and $\Ext P$ denote the interior and exterior of $\partial P$, when $\partial P$ is considered as a Jordan curve.

Proof
From Boundary of Polygon is Jordan Curve, it follows that $\partial P$ is equal to the image of a Jordan curve.

From the Jordan Polygon Theorem, it follows that $\Int P$ and $\Ext P$ are path-connected.

Then, Jordan Polygon Parity Lemma shows that $\map N q = \map {\operatorname{par} } q$, where $\map {\operatorname{par} } q$ denotes the parity of $q$.

From Jordan Polygon Theorem, it follows that $\Ext P$ is unbounded, while $\Int P$ is bounded.

As $\partial P$ is the image of a Jordan curve, it follows from Continuous Image of Compact Space is Compact/Corollary 2 that $\partial P$ is also bounded.

Then, there exists $R \in \R_{>0}$ such that $\Int P \cup \partial P \subseteq \map {B_R} \bszero$.

If $q_0 \in \R^2 \setminus \map {B_R} \bszero$, then $q_0 \in \Ext P$.

Then, the ray $\set {q_0 + s q_0: s \in \R_{\ge 0} } \subseteq \R^2 \setminus \map {B_R} \bszero$, so there are zero crossings between the ray and $\partial P$.

From Jordan Polygon Parity Lemma, it follows that $\map {\operatorname{par} } {q_0} = 0$.

As $\Ext P$ is path-connected, it follows from the lemma that for all $q \in \Ext P$, we have $\map {\operatorname{par} } q = 0$.

If $q_1 \in \R^2 \setminus \partial P$ with $\map {\operatorname{par} } q = 1$, it follows that $q_1 \notin \Ext P$.

As $\R^2 \setminus \partial P = \Int P \cup \Ext P$, it follows that $q_1 \in \Int P$.

From Jordan Polygon Parity Lemma:


 * $\forall q \in \Int P: \map {\operatorname{par} } q = 1$

So if instead $q_0 \in \R^2 \setminus \partial P$ with $\map {\operatorname{par} } q = 0$, the only possibility is that $q_0 \in \Ext P$.