Difference between revisions of "Theorem:Bolzano-Weierstrass"

Theorem 1 (Bolzano-Weierstrass): Let ${\displaystyle (a_{n})}$ be a bounded sequence. Then there exists a subsequence of ${\displaystyle (a_{n})}$, call it ${\displaystyle (a_{n_{k}})}$ that is convergent.

• Proof 1: Let ${\displaystyle (a_{n})}$ be a bounded sequence, that is the set ${\displaystyle \{a_{n}:n\in \mathbb {N} \}}$ is bounded. Suppose that ${\displaystyle a}$ is a lower bound for this set, and ${\displaystyle b}$ is an upper bound for this set, and so ${\displaystyle a\leq a_{n}\leq b_{n}}$ for all ${\displaystyle n\in \mathbb {N} }$. Therefore the set ${\displaystyle \{a_{n}:n\in \mathbb {N} \}}$ is contained in the interval ${\displaystyle I_{1}=[a,b]}$.

• Let's take ${\displaystyle n_{1}=1}$, i.e., let the first term of the subsequence ${\displaystyle (a_{n_{k}})}$ be equal to the first term of the parent sequence ${\displaystyle (a_{n})}$.

• We will now take the interval ${\displaystyle I_{1}}$ and divide into two subintervals of equal length. We will call these intervals ${\displaystyle I_{1}'}$ and ${\displaystyle I_{1}''}$. We will also divide the set of indices into two sets. Let ${\displaystyle A_{1}:=\{n\in \mathbb {N} :n>n_{1},a_{n}\in I_{1}'\}}$ and let ${\displaystyle B_{1}=\{n\in \mathbb {N} :n>n_{1},a_{N}\in I_{1}''\}}$. We note that ${\displaystyle A_{1}}$ is the set of indices ${\displaystyle n}$ greater than the first index in our subsequence, ${\displaystyle n_{1}}$, such that ${\displaystyle a_{n}}$ is in the interval ${\displaystyle I_{1}'}$. Similarly, ${\displaystyle B_{1}}$ is the set of indices ${\displaystyle n}$ greater than the first index in our subsequence, ${\displaystyle n_{1}}$ such that ${\displaystyle a_{N}}$ is in the interval ${\displaystyle I_{1}''}$.

• We note that both of the sets ${\displaystyle A_{1}}$ and ${\displaystyle B_{1}}$ cannot be finite since ${\displaystyle A_{1}}$ and ${\displaystyle B_{1}}$ contain all of the indices of the sequence ${\displaystyle (a_{n})}$ which has infinitely many indices since it is an infinite sequence. If ${\displaystyle A_{1}}$ is infinite, then we let ${\displaystyle I_{2}=I_{1}'}$, and we will let ${\displaystyle n_{2}}$ be the smallest natural number index in the set ${\displaystyle A_{1}}$, which we are ensured to have by the Well Ordering Principle. If ${\displaystyle A_{1}}$ is finite, then ${\displaystyle B_{1}}$ is infinite and we let ${\displaystyle I_{2}=I_{1}''}$ and we let ${\displaystyle n_{2}}$ be the smallest natural number index in the set ${\displaystyle B_{1}}$, which once again, we are ensured to have by the Well Ordering Principle.

• We will now take the interval ${\displaystyle I_{2}}$ and subdivide it into two subintervals of equal length, call them ${\displaystyle I_{2}'}$ and ${\displaystyle I_{2}''}$. Once again, we will subdivide the set of indices into two sets. Let ${\displaystyle A_{2}=\{n\in \mathbb {N} :n>n_{2},a_{n}\in I_{2}'\}}$ and let ${\displaystyle B_{2}=\{n\in \mathbb {N} :n>n_{2},a_{n}\in I_{2}''\}}$.

• Once again, if ${\displaystyle A_{2}}$ is infinite, then we will let ${\displaystyle I_{3}=I_{2}'}$, and let ${\displaystyle n_{3}}$ be the smallest natural number index of ${\displaystyle A_{2}}$. If ${\displaystyle A_{2}}$ is finite, then ${\displaystyle B_{2}}$ is infinite and let ${\displaystyle n_{3}}$ be the smallest natural number index of ${\displaystyle B_{2}}$.

• We will then take the interval ${\displaystyle I_{3}}$ and subdivide it into two subintervals of equal length, call them ${\displaystyle I_{3}'}$ and ${\displaystyle I_{3}''}$. We will also subdivide the set of indices into two sets. ${\displaystyle A_{3}=\{n\in \mathbb {N} :n>n_{3},a_{n}\in I_{3}'\}}$ and ${\displaystyle B_{3}=\{n\in \mathbb {N} :n>n_{3},a_{n}\in I_{3}''\}}$

• We will continue this pattern to obtain a sequence of nested intervals ${\displaystyle I_{1}\supseteq I_{2}\supseteq ...\supseteq I_{k}\supseteq ...}$. Furthermore, we will also have a subsequence ${\displaystyle (a_{n_{k}})}$ of ${\displaystyle (a_{n})}$ where ${\displaystyle a_{n_{k}}\in I_{k}}$ for every ${\displaystyle k\in \mathbb {N} }$.

• We also note that the length of any interval ${\displaystyle I_{k}}$ is precisely equal to ${\displaystyle {\frac {b-a}{2^{k-1}}}}$. By the nested intervals theorem there exists a common point ${\displaystyle \xi \in I_{k}}$ for all ${\displaystyle k\in \mathbb {N} }$, and so we have that:

${\displaystyle {\begin{aligned}\mid a_{n_{k}}-\xi \mid \leq {\frac {b-a}{2^{k-1}}}\end{aligned}}}$

• Therefore the subsequence ${\displaystyle (a_{n_{k}})}$ converges to ${\displaystyle \xi }$. ${\displaystyle \blacksquare }$

• Proof 2: Let ${\displaystyle (a_{n})}$ be a bounded sequence. By the <a href="/the-monotone-subsequence-theorem">The Monotone Subsequence Theorem</a>, every sequence of real numbers has a monotonic subsequence. Let ${\displaystyle (a_{n_{k}})}$ be this monotonic subsequence. Since ${\displaystyle (a_{n})}$ is bounded, it follows that ${\displaystyle (a_{n_{k}})}$ is also bounded since the values ${\displaystyle a_{n_{k}}}$ are contained in the sequence ${\displaystyle (a_{n})}$. Since ${\displaystyle (a_{n_{k}})}$ is both bounded and monotonic, then by <a href="/the-monotone-convergence-theorem">The Monotone Convergence Theorem</a>, ${\displaystyle (a_{n_{k}})}$ is a convergent subsequence. ${\displaystyle \blacksquare }$

Theorem 2: If ${\displaystyle (a_{n})}$ is a bounded sequence such that every convergent subsequence ${\displaystyle (a_{n_{k}})}$ of ${\displaystyle (a_{n})}$ converges to ${\displaystyle L}$ then ${\displaystyle (a_{n})}$ converges to ${\displaystyle L}$.

• Proof: Suppose that ${\displaystyle A=(a_{n})}$ does not converge to ${\displaystyle L}$. Then there exists a subsequence ${\displaystyle A'=(a_{n_{k}})}$ and an ${\displaystyle \epsilon _{0}>0}$ such that ${\displaystyle \mid a_{n_{k}}-L\mid \geq \epsilon _{0}}$ for all ${\displaystyle k\in \mathbb {N} }$.

• Since ${\displaystyle A}$ is bounded, any subsequence of ${\displaystyle A}$ is also bounded, and so the subsequence ${\displaystyle A'}$ is bounded. Since ${\displaystyle A'}$ is bounded, then by the Bolzano-Weierstrass theorem there exists a convergent subsequence ${\displaystyle A''}$ of ${\displaystyle A'}$. Since ${\displaystyle A''}$ is a convergent subsequence of ${\displaystyle A'}$, then it is also a convergent sequence of ${\displaystyle A}$ by transitivity, and by the hypothesis, ${\displaystyle A''}$ converges to ${\displaystyle L}$.

• But then convergence of ${\displaystyle A''}$ to ${\displaystyle L}$ contradicts the assumption that ${\displaystyle \mid a_{n_{k}}-L\mid \geq \epsilon _{0}}$, and so the assumption that ${\displaystyle A}$ did not converge to ${\displaystyle L}$ was false. Therefore ${\displaystyle (a_{n})}$ converges to ${\displaystyle L}$. ${\displaystyle \blacksquare }$

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