Let's choose an open covering for $\left [ 0,1 \right ]$. For example $\left \{ \left ( \frac 1 n,1-\frac 1 n \right ) \mid n\in \{ 3,4,\dots\} \right \}.$ How can one choose a finite open subcover to prove compactness?
Showing that $[0,1]$ is compact
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0Read the statement of compactness theorem again. WORD BY WORD. – 2018-12-19
4 Answers
Here is a quick and elegant proof of the actual result that $[0,1]$ is compact based on real induction:
Let $\mathcal{O}$ be an (arbitrary!) open cover. Let $P$ be the set of points $x$ in $[0,1]$ such that $[0,x]$ can be covered by finitely many elements of $\mathcal{O}$. We have $0\in P$ and $P$ is bounded above by $1$. Therefore, $P$ has a supremum $s$.
We first show that $[0,s]$ can be covered by finitely many sets in $\mathcal{O}$. This is trivial when $s=0$, so assume $s>0$. Let $O_s\in\mathcal{O}$ be a set containing $s$. Then there is an $\epsilon \in (0, s)$ such that $(s-\epsilon,s]\subseteq O_s$. By assumption, there is a finite subcover of $[0,s-\epsilon/2]$. By adding $O_s$ to that finite subcovering, we get a finite subcovering of $[0,s]$.
We now show that $s=1$. Suppose $s<1$ and let $O_s\in\mathcal{O}$ be a set containing $s$. Then there is an $\epsilon>0$ such that $[s,s+\epsilon)\subseteq O_s$. So taking a finite subcover of $[0,s]$ and adding the set $O_s$ gives us a finite subcover of $[0,s+\epsilon/2]$, contradicting the construction of $s$.
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0@StanShunpike That is basically the definition of an open set. If $O_s$ is open, there must be some "wiggle room" around each of its elements. In particular, if $s\in O_s$ then for some \epsilon>0, $(s-\epsilon, s+\epsilon)\subseteq O_s$. The result follows now from $(s-\epsilon,s]\subseteq (s-\epsilon,s+\epsilon)\subseteq O_s$. – 2015-07-10
The collection of sets above is not an open cover of $[0,1]$. The points $0$ and the point $1$ are not in any of them.
Also you can not prove compactness of anything by taking an open cover and finding a subcover.
The definition of compactness is that for all open covers, there exists a finite subcover.
If you want to prove compactness for the interval $[0,1]$, one way is to use the Heine-Borel Theorem that asserts that compact subsets of $\mathbb{R}$ are exactly those closed and bounded subsets.
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2Borel actually proved the theorem by showing that each closed and bounded interval is compact... – 2012-08-31
Answering your question would not prove compactness. The condition for compactness is that every open cover has a finite subcover, not just that a single given open cover has a finite subcover. A proof that $[0,1]$ is compact with respect to the Euclidean metric topology can be found here.
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0$EVERY$. A very important word. – 2018-12-19
I assume that you would like to prove that it is compact with respect to the usual topology. Since that topology is "generated" by a metric the topological compactness is equvalent with metrical compactness, i.e. the condition stating that every sequence has converging subsequence.
Observe that every sequence of elements of the interval $[0,1]$ is bounded. Therefore, by the Bolzano-Weierstrass theorem, it has a convergent subsequence.
Notice that the Bolzano-Weierstrass theorem can be proved by analytical arguments, so we are not in the vicious circle.
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1Proving the equivalence of compactness in terms of open coverings and proving the equivalence with sequential compactness is much, much harder than proving Heine-Borel in the one-dimensional case. – 2012-08-31