Closed Bounded Subset of Real Numbers is Compact/Proof 1

Theorem
Let $\R$ be the real number line considered as an Euclidean space.

Let $S \subseteq \R$ be a closed and bounded subspace of $\R$.

Then $S$ is compact in $\R$.

Proof
A closed and bounded subspace $S$ of $\R$ is a closed subspace of some closed real interval $\left[{a\,.\,.\,b}\right]$.

Since a closed subspace of a compact space is compact, it suffices to prove that $\left[{a\,.\,.\,b}\right]$ is compact.

Let $\mathcal U$ be any open cover of $\left[{a\,.\,.\,b}\right]$.

Let:
 * $G = \left\{{x \in \R: x \ge a, \left[{a \,.\,.\, x}\right] \text{ is covered by a finite subset of } \mathcal U}\right\}$

Let points in $G$ be classified as $\text{good}$ (for $\mathcal U$).

Thus if $z$ is $\text{good}$, then $\left[{a \,.\,.\, z}\right]$ has that finite subcover that is to be demonstrated for the whole of $\left[{a \,.\,.\, b}\right]$.

The aim therefore is to show that $b$ is $\text{good}$.

Let $x$ be $\text{good}$, and $a \le y \le x$.

We have that $\left[{a \,.\,.\, y}\right] \subseteq \left[{a\ ,.\,.\, x}\right]$.

Thus $\left[{a\,.\,.\,y}\right]$ can be covered with any finite subset of $\mathcal U$ that covers $\left[{a\,.\,.\,x}\right]$.

As $x$ be $\text{good}$, at least one such subset is known to exist.

Thus, by definition, $y$ is $\text{good}$.

Now we show that $G \ne \varnothing$.

At the same time we show that $G \supseteq \left[{a\,.\,.\,a + \delta}\right]$ for some $\delta > 0$.

As $\mathcal U$ covers $\left[{a \,.\,.\, x}\right]$, it follows that $a$ must belong to some $U \in \mathcal U$.

So, let $U \in \mathcal U$ be some open set such that $a \in U$.

Since $U$ is open, $\left[{a \,.\,.\,a + \delta}\right) \subseteq U$ for some $\delta > 0$.

Hence $\left[{a \,.\,.\, x}\right] \subseteq U$ for all $x \in \left[{a \,.\,.\,a + \delta}\right)$.

It follows that all these $x$ are $\text{good}$.

So $G \ne \varnothing$, and:
 * $(1): \quad G \supseteq \left[{a\,.\,.\,a + \delta}\right]$ for some $\delta > 0$

Now the non-empty set $G$ is either bounded above or it is not.

Suppose $G$ is not bounded above.

Then there is some $c$ which is $\text{good}$ such that $c > b$.

From our initial observation that if $x$ is $\text{good}$, and $a \le y \le x$, then $y$ is $\text{good}$, it follows that $b$ is $\text{good}$, and hence the result.

Now suppose $G$ is bounded above.

By the Continuum Property, $G$ admits a supremum in $\R$.

So let $g = \sup G$.

Let $g > b$.

As $g$ is the least upper bound for $G$, there exists some $c$ which is $\text{good}$ such that $c > b$.

Again, from our initial observation, it follows that $b$ is $\text{good}$, and hence the result.

Aiming for a contradiction, assume that $g \le b$.

From $(1)$ above:
 * $\left[{a\,.\,.\,a + \delta}\right) \subseteq G$ for some $\delta > 0$

and so $g > a$.

Since $g \in \left[{a \,.\,.\, b}\right]$, $g$ must belong to some $U_0 \in \mathcal U$.

Since $U_0$ is open, there exists some open $\epsilon$-ball $B_\epsilon \left({g}\right)$ of $g$ such that $U_0 \supseteq B_\epsilon \left({g}\right)$.

Since $g > a$, we can arrange that $\epsilon < g - a$.

As $g$ is the least upper bound, there must be a $\text{good}$ $c$ such that $c > g - \epsilon$.

This means $\left[{a \,.\,.\, c}\right]$ is covered by a finite subset of $\mathcal U$, say $\left\{{U_1, U_2, \ldots, U_r}\right\}$.

Then $\left[{a \,.\,.\, g + \dfrac \epsilon 2}\right]$ is covered by $\left\{{U_1, U_2, \ldots, U_r, U_0}\right\}$.

So $g + \dfrac \epsilon 2$ is $\text{good}$, contradicting the fact that $g$ is an upper bound for $G$.

This contradiction implies that $g > b$, and the proof is complete.