-
Notifications
You must be signed in to change notification settings - Fork 2
Commit
This commit does not belong to any branch on this repository, and may belong to a fork outside of the repository.
- Loading branch information
1 parent
759b679
commit a45dce2
Showing
2 changed files
with
45 additions
and
0 deletions.
There are no files selected for viewing
This file contains bidirectional Unicode text that may be interpreted or compiled differently than what appears below. To review, open the file in an editor that reveals hidden Unicode characters.
Learn more about bidirectional Unicode characters
| Original file line number | Diff line number | Diff line change |
|---|---|---|
|
|
@@ -208,15 +208,59 @@ \section*{Math 202A - Final Exam - Dan Davison - \texttt{[email protected]}} | |
|
|
||
| I wonder whether we can discard a null set from $V$ so that our point $x$ is necessarily | ||
| \end{proof} | ||
|
|
||
|
|
||
| \newpage | ||
| \begin{mdframed} | ||
| \includegraphics[width=400pt]{img/analysis--berkeley-202a-final-246a.png} | ||
| \end{mdframed} | ||
|
|
||
| \begin{proof} | ||
| $\mu$ is not a measure because it is not countably additive. | ||
|
|
||
| To see this, let $I_n = (-n, -(n - 1)] \union [n-1, n)$, and let $\mc I = \{I_n ~:~ n \in \N\}$. Then $\mc I$ | ||
| is a pairwise disjoint, countable collection of sets and $\bigcup_{n=1}^\infty \mc I = \R$, | ||
| therefore $\mu\(\bigcup_{n=1}^\infty \mc I\) = 1$ since $\R$ is unbounded. | ||
|
|
||
| However $I_n$ is bounded for all $n$ and | ||
| so $\sum_{n=1}^\infty \mu(I_n) = \sum_{n=1}^\infty 0 = 0 \neq \mu\(\bigcup_{n=1}^\infty \mc I\)$. | ||
| \end{proof} | ||
|
|
||
|
|
||
| \begin{mdframed} | ||
| \includegraphics[width=400pt]{img/analysis--berkeley-202a-final-cd70.png} | ||
| \end{mdframed} | ||
|
|
||
| \begin{proof} | ||
| Note that $f$ is continuous with compact support and so $f$ attains its bounds. Let $A = \inf f$ | ||
| and $B = \sup f$. | ||
|
|
||
| Note that the integrand is bounded above by the constant integrable function $h(x) = B$ defined on $[0, 1]$. | ||
| Therefore we may apply the dominated convergence theorem, yielding | ||
| \begin{align*} | ||
| \limninf \int_{[0, 1]} f(g(x)^n) \dx = \int_{[0, 1]} \limninf f(g(x)^n) \dx. | ||
| \end{align*} | ||
| Let $U = g^{-1}(\{1\})$. We have $0 \leq g(x) \leq 1$ and therefore | ||
| \begin{align*} | ||
| \limninf g(x)^n = | ||
| \begin{cases} | ||
| 1 & x \in U \\ | ||
| 0 & \text{otherwise}. | ||
| \end{cases} | ||
| \end{align*} | ||
| Since $g$ is measurable, $U$ is measurable, since it is a preimage of a measurable set. Let $\alpha = m(U)$. | ||
| I believe that ``measurable'' in the question refers to Lebesgue measure, so we have that $m([0, 1]) = 1$ | ||
| and $0 \leq \alpha \leq 1$. Therefore | ||
| \begin{align*} | ||
| \int_{[0, 1]} \limninf f(g(x)^n) \dx | ||
| &= \int_U \limninf f(g(x)^n) \dx + \int_{[0, 1] \setminus U} \limninf f(g(x)^n) \dx \\ | ||
| &= \int_U f(1) + \int_{[0, 1] \setminus U} f(0) \\ | ||
| &= \alpha f(1) + (1 - \alpha) f(0) \\ | ||
| &\in [f(0), f(1)]. | ||
| \end{align*} | ||
| \end{proof} | ||
|
|
||
|
|
||
| \newpage | ||
| \begin{mdframed} | ||
| \includegraphics[width=400pt]{img/analysis--berkeley-202a-final-f5b6.png} | ||
|
|
||
This file contains bidirectional Unicode text that may be interpreted or compiled differently than what appears below. To review, open the file in an editor that reveals hidden Unicode characters.
Learn more about bidirectional Unicode characters