Exercise 7

12. Let $(X, A, μ)$ be a measure space, $f$ an integrable function on $X$ and $A \subset X$ with $μ (A) < \infty$ . Prove that for some $x \in A$ ,

∣ f (x) ∣ \leq \frac{1}{μ ( A )} \int_{A} ∣ f ∣ d μ .

\begin{proof} Otherwise, for any $x \in A$ , $∣ f (x) ∣ > \frac{1}{μ ( A )} \int_{A} ∣ f ∣ d μ$ . It follows that

\int_{A} ∣ f ∣ d μ > \int_{A} (\frac{1}{μ ( A )} \int_{A} ∣ f ∣ d μ) d μ = μ (A) \cdot \frac{1}{μ ( A )} \int_{A} ∣ f ∣ d μ = \int_{A} ∣ f ∣ d μ,

which is impossible. Therefore, there exists some $x \in A$ such that $∣ f (x) ∣ \leq \frac{1}{μ ( A )} \int_{A} ∣ f ∣ d μ$ . \end{proof}

15. Let $(X, A, μ)$ be a $σ$ -finite measure space, $F \subset R$ a closed set, and $f$ an integrable function on $X$ such that

\frac{1}{μ ( A )} \int_{A} fd μ \in F for all A \in A with μ (A) < \infty

Prove that $f (x) \in F$ for a.e. $x \in X$ .

\begin{proof} Since $F$ is a closed set, $F^{c}$ is open and $F^{c}$ can be written as a countable union of disjoint open intervals. Assume that $F^{c} = \cup_{n = - \infty}^{\infty} (a_{n}, b_{n})$ , then $f^{- 1} (F^{c}) = \cup_{n = - \infty}^{\infty} f^{- 1} ((a_{n}, b_{n}))$ . If $μ (f^{- 1} (F^{c})) \neq = 0$ , then there exists at least one $n_{0}$ such that $μ (f^{- 1} ((a_{n_{0}}, b_{n_{0}}))) \neq = 0$ and $(a_{n_{0}}, b_{n_{0}}) \cap F = \emptyset$ .

Define $S = f^{- 1} ((a_{n_{0}}, b_{n_{0}}))$ . Since $f$ is integrable, $S \in A$ and so

\frac{1}{μ ( S )} \int_{S} fd μ \in (a_{n_{0}}, b_{n_{0}}),

which contradicts with $(a_{n_{0}}, b_{n_{0}}) \cap F = \emptyset$ . Therefore, $f (x) \in F$ for a.e. $x \in X$ . \end{proof}

16. Let $(X, A, μ)$ be a measure space and $f \in L^{1} (μ)$ such that $\int_{A} fd μ \leq$ $c μ (A)$ for all measurable $A$ with $μ (A) < \infty$ and a constant $c$ . Prove that $∣ f ∣ \leq c$ a.e.

\begin{proof} Define $S = f^{- 1} ((c, \infty))$ . If $μ (S) \neq = 0$ , then

\frac{1}{μ ( S )} \int_{S} fd μ > c,

which is impossible. Therefore, $μ (S) = 0$ , i.e., $∣ f ∣ < c$ a.e. \end{proof}

18. Give a proof of Proposition 8.7.

Proposition 8.7 Let $(X, A, μ)$ be a measure space and let $f$ and $g$ be integrable, complex-valued functions defined on $X$ . Let $α$ and $β$ be complex constants. Then
$\int_{X} (α f + β g) d μ = α \int_{X} fd μ + β \int_{X} g d μ$

\begin{proof} Suppose $α = α_{1} + α_{2} i$ and $β = β_{1} + β_{2} i$ with $α_{i}, β_{i} \in R$ . Suppose $f = f_{1} + f_{2} i$ and $g = g_{1} + g_{2} i$ with $f_{i}, g_{i}$ are integrable real-valued functions. Then we have

LHS = \int_{X} (α_{1} f_{1} - α_{2} f_{2} + β_{1} g_{1} - β_{2} g_{2}) d μ + i \int_{X} (α_{1} f_{2} + α_{2} f_{1} + β_{1} g_{2} + β_{2} g_{1}) d μ

and

RHS = (α_{1} + α_{2} i) (\int_{X} f_{1} d μ + i \int_{X} f_{2} d μ) + (β_{1} + β_{2} i) (\int_{X} g_{1} d μ + i \int_{X} g_{2} d μ) .

It suffices to show

\int_{X} (α_{1} f_{1} - α_{2} f_{2} + β_{1} g_{1} - β_{2} g_{2}) d μ = α_{1} \int_{X} f_{1} d μ - α_{2} \int_{X} f_{2} d μ + β_{1} \int_{X} g_{1} d μ - β_{2} \int_{X} g_{2} d μ

and the proof of another equality is similar. By Theorem 8.6, we finish the proof. \end{proof}

Exercise 8

1. Suppose $μ$ is a signed measure. Prove that $A$ is a null set with respect to $μ$ if and only if $∣ μ ∣ (A) = 0$ .

\begin{proof} By Hahn decomposition, there exist disjoint $E$ and $F$ such that $E ⊔ F = X$ , $E$ is a negative set and $F$ is a positive set. Thus $A = (A \cap E) ⊔ (A \cap F)$ .

If $A$ is a null set, then for any $B \subseteq A$ and $B \in A$ we have $μ (B) = 0$ . If $μ^{-} (A \cap E) \neq = 0$ , then $μ (A \cap E) = μ^{+} (A \cap E) - μ^{-} (A \cap E) \neq = 0$ by $μ^{+} (A \cap E) = 0$ , which is impossible. Hence, $μ^{-} (A \cap E) = 0$ . Similarly, we can prove that $μ^{+} (A \cap F) = 0$ . It deduces that $μ^{+} (A) = μ^{+} (A \cap F) = 0$ and $μ^{-} (A) = μ^{-} (A \cap E) = 0$ . Therefore, $∣ μ ∣ (A) = 0$ .

If $∣ μ ∣ (A) = 0$ , then $μ^{+} (A) = μ (A \cap E) = 0$ and $μ^{-} (A) = μ (A \cap F) = 0$ . For any subset $B \subseteq A$ , we have $μ (B) = μ^{+} (B) - μ^{-} (B)$ . Since $μ^{+}$ and $μ^{-}$ are measures, $μ^{+} (B) ⩽ μ^{+} (A) = 0$ and $μ^{-} (B) ⩽ μ^{-} (A) = 0$ . Therefore, $μ (B) = 0$ for any $B \subseteq A$ and so $A$ is a null set. \end{proof}

2. Let $μ$ be a signed measure on a measurable space $(X, A)$ and $f$ be a measurable function on $X$ . Prove that

\int_{E} fd μ \leq \int_{E} ∣ f ∣ d ∣ μ ∣, \forall E \in A .

\begin{proof} Recall that integration with respect to a signed measure $μ$ is defined as

\int_{X} fd μ = \int_{X} fd μ^{+} - \int_{X} fd μ^{-} .

Since $∣ μ ∣ = μ^{+} + μ^{-}$ , we have $\int_{E} ∣ f ∣ d ∣ μ ∣ = \int_{E} ∣ f ∣ d μ^{+} + \int_{E} ∣ f ∣ d μ^{-}$ . Then $\int_{E} ∣ f ∣ d μ^{+} ⩾ \pm \int_{E} fd μ^{+}$ and $\int_{E} ∣ f ∣ d μ^{-} ⩾ \pm \int_{E} fd μ^{-}$ yield that

\int_{E} ∣ f ∣ d ∣ μ ∣ = \int_{E} ∣ f ∣ d μ^{+} + \int_{E} ∣ f ∣ d μ^{-} ⩾ \int_{E} fd μ^{+} - \int_{E} fd μ^{-} = \int_{E} f μ

and

\int_{E} ∣ f ∣ d ∣ μ ∣ = \int_{E} ∣ f ∣ d μ^{+} + \int_{E} ∣ f ∣ d μ^{-} ⩾ - \int_{E} fd μ^{+} + \int_{E} fd μ^{-} = - \int_{E} f μ .

Now we finish the proof. \end{proof}

3. Let $μ$ be a signed measure on $(X, A)$ . Prove that if $A \in A$ , then

∣ μ ∣ (A) = sup {j = 1 \sum n ∣ μ (B_{j}) ∣, each B_{j} \in A, the B_{j} are disjoint, \cup_{j = 1}^{n} B_{j} = A} .

\begin{proof} By Hahn decomposition, there exist disjoint $E$ and $F$ such that $E ⊔ F = X$ , $E$ is a negative set and $F$ is a positive set. Thus $A = (A \cap E) ⊔ (A \cap F)$ .

For any disjoint $B_{j}$ with $⊔_{j = 1}^{n} B_{j} = A$ , there is

j = 1 \sum n ∣ μ (B_{j}) ∣ ⩽ j = 1 \sum n ∣ μ ∣ (B_{j}) = ∣ μ ∣ (A)

and so

∣ μ ∣ (A) ⩽ sup {j = 1 \sum n ∣ μ (B_{j}) ∣, each B_{j} \in A, the B_{j} are disjoint, \cup_{j = 1}^{n} B_{j} = A} .

On the other hand, for any disjoint $B_{j}$ with $⊔_{j = 1}^{n} B_{j} = A$ , define $B_{j 1} = B_{j} \cap E$ and $B_{j 2} = B_{j} \cap F$ , then ${B_{j 1}} \cup {B_{j 2}}$ is a pairwise disjoint family whose union equals $A$ . Note that $∣ μ (B_{j 1}) ∣ = ∣ μ (B_{j} \cap E) ∣ = ∣ μ^{+} (B_{j}) ∣ = μ^{+} (B_{j})$ and $∣ μ (B_{j 2}) ∣ = ∣ μ (B_{j} \cap F) ∣ = ∣ μ^{-} (B_{j}) ∣ = μ^{-} (B_{j})$ , we have

k = 1 \sum 2 j = 1 \sum n ∣ μ (B_{jk}) ∣ = j = 1 \sum n ∣ μ ∣ (B_{j}) = ∣ μ ∣ (A)

and so $∣ μ ∣ (A) = sup {\sum_{j = 1}^{n} ∣ μ (B_{j}) ∣, each B_{j} \in A, the B_{j} are disjoint, \cup_{j = 1}^{n} B_{j} = A}$ . \end{proof}

4. If $μ = μ_{1} - μ_{2}$ , where $μ_{1}, μ_{2}$ are positive measures and either $μ_{1}$ or $μ_{2}$ is finite, then $μ_{1} (E) \geq μ^{+} (E), μ_{2} (E) \geq μ^{-} (E)$ , for all $E \in A$ , where $μ = μ^{+} - μ^{-}$ is the Jordan decomposition of $μ$ .

\begin{proof} By Hahn decomposition, there exist disjoint $M$ and $N$ such that $M ⊔ N = X$ , $M$ is a negative set and $N$ is a positive set. Then for any $E \in A$ , $E = (E \cap M) ⊔ (E \cap N)$ . Note that

μ_{1} (E \cap M) - μ_{2} (E \cap M) = μ (E \cap M) = μ^{+} (E \cap M) - μ^{-} (E \cap M) = μ^{+} (E \cap M)

yields that $μ_{1} (E \cap M) = μ_{2} (E \cap M) + μ^{+} (E \cap M) ⩾ μ^{+} (E \cap M)$ . Also we have $μ_{1} (E \cap N) ⩾ 0 = μ^{+} (E \cap N)$ . Thus, $μ_{1} (E) ⩾ μ^{+} (E)$ .

On the other hand, as $μ_{2} (E) - μ^{-} (E) = μ_{1} (E) - μ^{+} (E) ⩾ 0$ , there is $μ_{2} (E) ⩾ μ^{-} (E)$ . \end{proof}

5. Let $(X, A, μ)$ be a finite signed measure space. Show that there is an $M > 0$ such that $∣ μ (E) ∣ < M$ for every $E \in A$ .

\begin{proof} Since $μ$ is a finite signed measure, $μ^{+} (X)$ and $μ^{-} (X)$ are finite. Assume that $N > 0$ is a real number such that $μ^{+} (X) ⩽ N$ and $μ^{-} (X) ⩽ N$ . For any $E \in A$ , we have

∣ μ (E) ∣ = ∣ μ^{+} (E) - μ^{-} (E) ∣ ⩽ μ^{+} (E) + μ^{-} (E) ⩽ μ^{+} (X) + μ^{-} (X) ⩽ N

and so $M = 2 N + 1$ is what we desired. \end{proof}

7. Let $(X, A, μ)$ be a signed measure space. Then, for every $E \in A$ ; the following hold:

(a) $μ^{+} (E) = sup {μ (F) : F \subset E, F \in A}$ ;
(b) $μ^{-} (E) = sup {- μ (F) : F \subset E, F \in A}$ .

\begin{proof} By Hahn decomposition, there exist disjoint $M$ and $N$ such that $M ⊔ N = X$ , $M$ is a negative set and $N$ is a positive set.

(a) Note that $μ^{+} (E) = μ (E \cap M)$ and $E \cap M \subseteq E$ , then we have $μ^{+} (E) ⩽ sup {μ (F) : F \subset E, F \in A}$ . For any $F \subseteq E$ ,

μ (F) = μ^{+} (F) - μ^{-} (F) ⩽ μ^{+} (E) - μ^{-} (F) ⩽ μ^{+} (E)

yields that $μ^{+} (E) ⩾ sup {μ (F) : F \subset E, F \in A}$ . Therefore, $μ^{+} (E) = sup {μ (F) : F \subset E, F \in A}$ .

(b) Similarly, note that $μ^{-} (E) = - μ (E \cap N)$ and $E \cap N \subseteq E$ , then we have $μ^{-} (E) ⩽ sup {- μ (F) : F \subset E, F \in A}$ . For any $F \subseteq E$ ,

μ (F) = μ^{+} (F) - μ^{-} (F) ⩾ μ^{+} (F) - μ^{-} (E) ⩾ - μ^{-} (E)

yields that $μ^{-} (E) ⩾ sup {- μ (F) : F \subset E, F \in A}$ . Therefore, $μ^{-} (E) = sup {- μ (F) : F \subset E, F \in A}$ . \end{proof}

9. Let $(X, A, μ)$ be a $σ$ -finite measure space and let $ν$ be a measure on $(X, A)$ for which the conclusion of the Radon-Nikodym Theorem holds. Prove that $ν$ is $σ$ -finite.

\begin{proof} We aim to show $ν (A) = \int_{A} fd μ$ is $σ$ -finite, where $f$ is a finite real-valued measurable function. Since $μ$ is $σ$ -finite, there exists ${E_{n}}_{n = 1}^{\infty}$ such that $E_{n} ↑ X$ and $μ (E_{n}) < \infty$ .

As $f$ is measurable, define $E_{n}^{'} = f^{- 1} ([- n, n]) \cap E_{n}$ and then $E_{n}^{'} ↑ X$ . Since $ν (E_{n}^{'}) = \int_{E_{n}^{'}} fd μ ⩽ μ (E_{n}) \cdot n < \infty$ , $ν$ is $σ$ -finite. \end{proof}

10. Let $μ$ and $ν$ be measures on the measurable space $(X, A)$ . Show that the absolute continuity condition is equivalent to $μ (A Δ B) = 0 \Rightarrow ν (A) = ν (B)$ for all $A, B \in A$ .

\begin{proof} Assume the absolute continuity condition holds, that is, if $μ (A) = 0$ , then $ν (A) = 0$ . If $μ (A Δ B) = 0$ , then $ν (A \cap B^{c}) = ν (A^{c} \cap B) = 0$ and so

ν (A) = ν (A \cap B) + ν (A \cap B^{c}) = ν (A \cap B) + ν (A^{c} \cap B) = ν (B) .

Conversely, assume $μ (A Δ B) = 0 \Rightarrow ν (A) = ν (B)$ for all $A, B \in A$ . Then if $μ (A) = 0$ , then $A Δ\emptyset = A$ and so $ν (A) = ν (\emptyset) = 0$ . \end{proof}

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