Exercise 5

7. Let $T : X \to Y$ be a map. Show that $T^{- 1} (σ (G)) = σ (T^{- 1} (G))$ holds for any families $G$ of subsets of $Y$ .

\begin{proof} By homework 1 exercise 9, for any $σ$ -algebra on $Y$ , $T^{- 1} (Y)$ is also a $σ$ -algebra. Thus, it follows that $T^{- 1} (σ (G)) \supseteq σ (T^{- 1} (G))$ as $T^{- 1} (G) \subseteq T^{- 1} (σ (G))$ .

On the other hand, it is easy to show that $T (\cup_{i = 1}^{\infty} T^{- 1} (A_{i})) = \cup_{i = 1}^{\infty} T^{- 1} (A_{i})$ and $T (T^{- 1} (A^{c})) = (T (T^{- 1} (A)))^{c}$ . Thus, for any $A \in σ (T^{- 1} (G))$ , we have that $T (A) \in σ (G)$ and $A \in T^{- 1} (σ (G))$ . Therefore, $T^{- 1} (σ (G)) \supseteq σ (T^{- 1} (G))$ and so $T^{- 1} (σ (G)) = σ (T^{- 1} (G))$ . \end{proof}

8. Let $(X, A)$ be a measurable space.

(i) Let $f, g : X \to R$ be measurable functions. Show that for every $A \in A$ the function $h (x) := f (x)$ , if $x \in A$ , and $h (x) := g (x)$ , if $x \in / A$ , is measurable.
(ii) Let ${f_{n}}$ be a sequence of measurable functions and let ${A_{n}} \subset A$ such that $\cup_{n} A_{n} = X$ . Suppose that $f_{n} ∣_{A_{n} \cap A_{k}} = f_{k} ∣_{A_{n} \cap A_{k}}$ for all $k, n \in N$ and set $f (x) := f_{n} (x)$ if $x \in A_{n}$ . Show that $f : X \to R$ is measurable.

\begin{proof} i) For any open subset $U \subseteq R$ , $h^{- 1} (U) = (f^{- 1} (U) \cap A) \cup (g^{- 1} (U) \cap A^{c})$ . Since $f, g$ are measurable functions, $f^{- 1} (U)$ and $g^{- 1} (U)$ are measurable. Note that $A, A^{c}$ are measurable, then $h^{- 1} (U)$ is measurable and so $h$ is a measurable function.

ii) Since $f_{n} ∣_{A_{n} \cap A_{k}} = f_{k} ∣_{A_{n} \cap A_{k}}$ , $f$ is well-defined. Note that for any open subset $U \subseteq R$ ,

f^{- 1} (U) = n = 1 ⋃ \infty (f_{n}^{- 1} (U) \cap A_{n})

where $f_{n}^{- 1} (U)$ are measurable for all $n \in N_{+}$ . Therefore, $f^{- 1} (U)$ is measurable. \end{proof}

9. Show that any left- or right-continuous function $u : R \to R$ is measurable.

\begin{proof} Assume that $u$ is left-continuous.

Firstly, we claim that $u$ has only countable discontinuities. Define $A := {x \in R : u \mbox i s n o t co n t in u o u so n x}$ . Suppose for contradiction that $A$ is uncountable. For $i \in Z^{+}$ , let $A_{i}$ be the set of all $a \in A$ such that, for any neighborhood $U$ of $a$ , $∣ f (x) - f (y) ∣ ⩾ 1/ i$ holds for some $x, y \in U$ . Since $f$ is discontinuous on $A$ , we have $A = ⋃_{i = 1}^{\infty} A_{i}$ and it follows that $A_{n}$ is uncountable for some $n$ . Call a point $a \in A_{n}$ left-isolated if $(a - ϵ, a)$ does not meet $A_{n}$ for sufficiently small $ϵ > 0$ . By associating to each left isolated point $a$ a rational number from the interval ( $a - ϵ, a$ ), we see that $A_{n}$ has countably many left-isolated points. Since $A_{n}$ is uncountable, there exists some $p \in A_{n}$ which is not left isolated. For any $ϵ > 0$ , we have that $(p - ϵ, p)$ is a neighborhood of some $a \in A_{n}$ . Hence, $∣ u (x) - u (y) ∣ ⩾ 1/ n$ for some $x, y \in (p - ϵ, p)$ , which contradicts the assumption that the limit as $x \to p$ from the left of $u (x)$ exists.

To show $u$ is continuous, it suffices to show $u^{- 1} ((a, \infty])$ is measurable for every $a \in R$ . Assume that $u^{- 1} ((a, \infty]) = A$ and ${a_{i}}_{i \in I} \in R \cup {- \infty, \infty}$ is the set of countable discontinuities with $a_{n} < a_{m}$ if $n < m$ and $I \subseteq N_{+}$ . Since $u ∣_{(a_{n}, a_{n + 1}]}$ is continuous for all $n, n + 1 \in I$ , we have that $(u ∣_{(a_{n}, a_{n + 1}]})^{- 1} ((a, \infty]) = A \cap (a_{n}, a_{n + 1}]$ is measurable. Note that

A = \cup_{n, n + 1 \in I} ((a_{n}, a_{n + 1}] \cap A)

is measurable and so $u$ is measurable.

If $u$ is right-continuous, then $- u$ is left-continuous and it is measurable. It follows that $u$ is measurable. \end{proof}

10. Let $f : R^{n} \to R^{n}$ be continuous, 1-1, and onto. Prove that $f$ maps Borel sets onto Borel sets.

\begin{proof} Note that $f$ is Borel measurable by $f$ continuous. Let $B$ be the Borel sets of $R^{n}$ . Then for any $B \in B$ , we have that $f^{- 1} (B) \in B$ . Define

φ : B \to B, B \mapsto f^{- 1} (B) .

Assume that there exist distinct $B_{1}, B_{2} \in B$ such that $φ (B_{1}) = φ (B_{2})$ , then it follows that $f^{- 1} (B_{1}) = f^{- 1} (B_{2})$ and $f (f^{- 1} (B_{1})) = f (f^{- 1} (B_{1}))$ , which is impossible. Therefore, $f$ is injective.

For each $B \in B$ , there exists $φ (B) \in B$ such that $f (φ (B)) = B$ and so $f$ maps Borel sets onto Borel sets. \end{proof}

Exercise 6

1. Suppose $f_{n}$ are measurable functions. Prove that

A = {x : n \to \infty lim f_{n} (x) exists}

is a measurable set.

\begin{proof} Let $g (x) = lim sup_{n \to \infty} f_{n} (x)$ and let $h (x) = lim in f_{n \to \infty} f_{n} (x)$ . Then $g$ and $h$ are measurable functions. Note that $A = {x : g (x) = h (x)} = (g - h)^{- 1} (0)$ and $g - h$ is measurable, so it deduces that $A$ is measurable set. \end{proof}

2. Suppose $(X, A)$ is a measurable space, $f$ is a real-valued function, and ${x : f (x) > r} \in A$ for each rational number $r$ . Prove that $f$ is measurable.

\begin{proof} As ${x : f (x) > r} \in A$ for all $r \in Q$ , we have that $f^{- 1} ((r, \infty])$ is measurable for all $r \in Q$ . For any $s \in R ∖ Q$ , there exists ${r_{n}} \subseteq Q$ such that $r_{n}$ is a decreasing sequence and $r_{n} \to s, n \to \infty$ . Define $A_{n} = {x : f (x) > r_{n}}$ , then ${A_{n}}_{n = 1}^{\infty}$ is a sequence of measurable sets and so $\cup_{n = 1}^{\infty} A_{n} \in A$ . Note that

\cup_{i = 1}^{\infty} A_{n} = {x : f (x) > s} = f^{- 1} ((s, \infty])

is measurable. Therefore, for every $a \in R$ , $f^{- 1} ((a, \infty])$ is measurable and so $f$ is measurable. \end{proof}

4. Let $(X, A)$ be a measurable space. If $X = A \cup B$ where $A, B \in A$ . Show that a function $f$ on $X$ is measurable iff $f$ is measurable on $A$ and on $B$ .

\begin{proof} Assume that $f$ is measurable on $X$ and $f : X \to Y$ with measurable space $(Y, C)$ . We aim to show $f$ is measurable on $A$ and $B$ . Note that for any $C \in C$ ,

(f ∣_{A})^{- 1} (C) = f^{- 1} (C) \cap A

is measurable. Therefore, $f$ is measurable on $A$ . Similarly, we can prove that $f$ is measurable on $B$ .

Now we assume that $f$ is measurable on $A$ and $B$ . For any $C \in C$ , by $X = A \cup B$ , we have that

f^{- 1} (C) = ((f ∣_{A})^{- 1} (C)) \cup ((f ∣_{b})^{- 1} (C)) .

Since $(f ∣_{A})^{- 1} (C)$ and $(f ∣_{B})^{- 1} (C)$ are measurable, $f^{- 1} (C)$ is also measurable. Therefore, $f$ is measurable on $X$ . \end{proof}

5. Let $(X, A, μ)$ be a measure space and ${f_{n}}, f$ measurable functions on $X$ . Prove:

{x \in X : n \to \infty lim f_{n} (x) \neq = f (x)} = \cup_{k = 1}^{\infty} \cap_{m = k}^{\infty} {x : n > m sup ∣ f_{n} (x) - f (x) ∣ > 1/ k} .

\begin{proof} For any $x \in \cup_{k = 1}^{\infty} \cap_{m = k}^{\infty} {x : sup_{n > m} ∣ f_{n} (x) - f (x) ∣ > 1/ k}$ , there exists $k \in N_{+}$ such that $x \in \cap_{m = k}^{\infty} {x : sup_{n > m} ∣ f_{n} (x) - f (x) ∣ > 1/ k}$ . Hence, for any $N \in N_{+}$ , there exists $n > N$ such that $∣ f_{n} (x) - f (x) ∣ > 1/ k$ and so $f_{n} (x) \neq \to f (x)$ as $n \to \infty$ . Therefore, $x \in {x \in X : lim_{n \to \infty} f_{n} (x) \neq = f (x)}$ .

For any $x \in {x \in X : lim_{n \to \infty} f_{n} (x) \neq = f (x)}$ , either $f (x) \neq = lim sup_{n \to \infty} f_{n} (x)$ or $f (x) \neq = lim inf_{n \to \infty} f_{n} (x)$ holds. If $f (x) \neq = lim sup_{n \to \infty} f_{n} (x)$ , then there exists $k \in N_{+}$ such that

∣ f (x) - n \to \infty lim sup f_{n} (x) ∣ > \frac{1}{k}

and so for any $N$ there exists $n > N$ such that $∣ f_{n} (x) - f (x) ∣ > \frac{1}{k}$ . Therefore, $x \in \cup_{k = 1}^{\infty} \cap_{m = k}^{\infty} {x : sup_{n > m} ∣ f_{n} (x) - f (x) ∣ > 1/ k}$ . Similarly, if $f (x) \neq = lim inf_{n \to \infty} f_{n} (x)$ , we can also prove that $x \in \cup_{k = 1}^{\infty} \cap_{m = k}^{\infty} {x : sup_{n > m} ∣ f_{n} (x) - f (x) ∣ > 1/ k}$ .

Now we finish the proof. \end{proof}

8. Let $(X, A, μ)$ be a measure space and ${f_{n}}$ a monotone sequence of measurable functions on $X$ that converges to $f$ in measure. Prove that $lim_{n \to \infty} f_{n} = f$ a.e.

\begin{proof} Define $E_{m, n} = {x \in X : ∣ f_{m} (x) - f (x) ∣ ⩾ \frac{1}{n}}$ , then ${E_{m, n}}_{m = 1}^{\infty}$ is decreasing monotonic sequences and $μ (\cup_{n = 1}^{\infty} \cap_{m = 1}^{\infty} E_{m, n}) = 0$ .

Define $L := {x : f_{n} (x) \to f (x)}$ . For any $x \neq \in L$ , since ${f_{n}}$ is monotone, $f_{n} (x)$ converges to $g (x)$ and $∣ g (x) - f (x) ∣ > 0$ . It follows that there exists $M, N$ such that $x \in E_{m, n}$ for any $m > M$ and $n > N$ . Therefore, $L \subseteq \cup_{n = 1}^{\infty} \cap_{m = 1}^{\infty} E_{m, n}$ and so $lim_{n \to \infty} f_{n} = f$ a.e. by $μ (L^{c}) = 0$ . \end{proof}

9. Let $(X, A, μ)$ be a measure space. Let $f$ be a real-valued measurable function on a set $D \in A$ with $μ (D) < \infty$ . Show that for every $ϵ > 0$ there exists a set $E \in A$ such that $E \subset D, μ (D - E) < ϵ$ and $f$ is bounded on $D - E$ .

\begin{proof} Since $f$ is measurable, there exists a sequence ${f_{n}}$ such that $f_{n} \to f$ pointwise, each $f_{n}$ are simple functions and $∣ f_{n} (x) ∣ ⩽ ∣ f_{n + 1} (x) ∣ ⩽ ∣ f (x) ∣$ for all $n \in N$ and all $x \in X$ . By Egorov’s theorem, for any $ϵ > 0$ there exists $E \subseteq D$ such that $μ (D - E) < ϵ$ and $f_{n} \to f$ uniformly on $E$ . Furthermore, since $f_{n}$ are bounded function, it yields that $f$ is bounded on $E$ . \end{proof}

11. Let $f$ be a bounded real-valued measurable function on a measure space $(X, A, μ)$ .

(a) Show that there exists an increasing sequence of simple functions ${f_{n}}$ , such that $f_{n} ↑ f$ uniformly.
(b) Show that there exists a decreasing sequence of simple functions ${g_{n}}$ , such that $g_{n} ↓ f$ uniformly.

\begin{proof} a) Define $f = f^{+} - f^{-}$ where

f(x), &\mbox{if }f(x)\geqslant0\\ \\ 0,&\mbox{if }f(x)<0 \end{cases}\mbox{ and } f^-(x)=\begin{cases} 0, &\mbox{if }f(x)\geqslant0\\ \\ -f(x),&\mbox{if }f(x)<0 \end{cases}.$$ Since $f$ is bounded, we assume that $|f(x)|\leqslant M$ for all $M$. By Theorem 7.3, there exists sequences $\{f_n\}$ and $\{g_n\}$ such that $f_n,g_n$ are simple functions, $f_n\to f^+, g_n\to M-f^-$ and $|f_k(x)|\leqslant|f_{k+1}(x)|$, $|g_k(x)|\leqslant|g_{k+1}(x)|$ for all $k\in \mathbb{N}$. Since $f_n(x)\geqslant 0$ for all $x\in X$ and $g_n(x)\geqslant 0$ for all $x\in X$, it follows that $\{f_n\}$ and $\{g_n\}$ are increasing sequence. Define $h_n(x)=f_n(x)+g_n(x)-M$, then $\{h_n\}$ is an increasing sequence and $h_n\to f$. Since $f^+$ and $M-f^-$ are bounded functions, $\{f_n\}$ are $\{g_n\}$ are uniformly convergent. It follows that $\{h_n\}$ is uniformly convergent to $f$, as desired. b) Define $F(x)=-f(x)$, then $F$ is also a bounded real-valued measurable function and there exists increasing sequence $\{F_n\}$ such that $F_n\to F$ uniformly by a). Define $k_n=-F_n$, then $\{k_n\}$ is a decreasing sequence and $k_n\to f$ uniformly, as desired. `\end{proof}`

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