Exercise 9

1. (i) Assume $0 < \int_{X} f^{p} d μ < \infty$ and $0 < \int_{X} g^{q} d μ < \infty$ . Prove that equality holds in (10.3) if and only if there exists a constant $α > 0$ such that $g^{q} = α f^{p}$ almost everywhere. (Hint. Use the proof of the Hölder inequality and the fact that equality holds in (9.2) if and only $p^{p} = b^{q}$ .)

\int_{X} f g d μ \leq (\int_{X} f^{p} d μ)^{1/ p} (\int_{X} g^{q} d μ)^{1/ q} (10.3)

(ii) Assume $0 < \int_{X} f^{p} d μ < \infty$ and $0 < \int_{X} g^{q} d μ < \infty$ Prove that equality holds in (9.4) if and only if there exists a constant $β > 0$ such that $g = β f$ almost everywhere. Hint. Use part (i) and the proof of the Minkowski inequality.

(\int_{X} (f + g)^{p} d μ)^{1/ p} \leq (\int_{X} f^{p} d μ)^{1/ p} + (\int_{X} g^{q} d μ)^{1/ q} (10.4)

\begin{proof} i) If $g^{q} = α f^{p}$ , then

LHS = (\int_{X} f^{p} d μ)^{1/ p} (\int_{X} g^{q} d μ)^{1/ q} = (\int_{X} f^{p} d μ)^{1/ p} (\int_{X} α f^{p} d μ)^{1/ q} = α^{1/ q} \int_{X} f^{p}

and $RHS = \int_{X} f \cdot α^{1/ p} f^{p / q} d μ = α^{1/ q} \int_{X} f^{p} d μ$ . Hence , the equality holds.

Conversely, assume that the inequality holds. In the proof of Holder inequality, take $f_{1} = c_{1} f$ and $g_{1} = c_{2} g$ such that $c_{i} > 0$ and $\int_{X} f_{1}^{p} d μ = \int_{X} g_{1}^{q} d μ = 1$ , and then

\int_{X} f_{1} g_{1} d μ \leq \int_{X} (\frac{f _{1}^{p}}{p} + \frac{g _{1}^{q}}{q}) d μ = 1 = (\int_{X} f_{1}^{p} d μ)^{1/ p} (\int_{X} g_{1}^{q} d μ)^{1/ q}

yields that $f_{1} g_{1} = f_{1}^{p} / p + g_{1}^{q} / q$ and Young’s inequality holds. Hence, $f_{1}^{p} = g_{1}^{q}$ almost everywhere. Therefore, there exists a constant $β > 0$ such that $g = β f$ .

ii) If $g = β f$ , then

LHS = (\int_{X} (f + β f)^{p} d μ)^{1/ p} = (1 + β) (\int_{X} f^{p} d μ)^{1/ p}

and

RHS = (\int_{X} f^{p} d μ)^{1/ p} + (\int_{X} (β f)^{p} d μ)^{1/ p} = (1 + β) (\int_{X} f^{p} d μ)^{1/ p} = LHS .

On the other hand, assume that the inequality holds. Then in the proof of Minkowski inequality

\leq \int_{X} f (f + g)^{p - 1} d μ + \int_{X} g (f + g)^{p - 1} d μ (\int_{X} f^{p} d μ)^{1/ p} (\int_{X} (f + g)^{(p - 1) q} d μ)^{1/ q} + (\int_{X} g^{p} d μ)^{1/ p} (\int_{X} (f + g)^{(p - 1) q} d μ)^{1/ q}

holds iff $α f^{p} = (f + g)^{(p - 1) q} = β g^{p}$ . Therefore, there exists a constant $c$ such that $g = c f$ . \end{proof}

3. Let $f \in L^{\infty} (μ)$ . Show that there exists a measurable set $E \subset A$ such that

μ (E) = 0 and X - E sup ∣ f ∣ = ∥ f ∥_{\infty} .

\begin{proof} Define $E = {x : ∣ f (x) ∣ > ∣∣ f ∣ ∣_{\infty}}$ , then $μ (E) = 0$ by lemma 10.6. By the definition of $E$ , $sup_{X - E} ∣ f ∣ ⩽ ∣∣ f ∣ ∣_{\infty}$ . On the other hand, if $sup_{X - E} ∣ f ∣ > ∣∣ f ∣ ∣_{\infty}$ , there exists $x \in X ∖ E$ such that $∣ f (x) ∣ ⩾ ∣∣ f ∣ ∣_{\infty}$ and so $x \in E$ , contradiction. Hence, $sup_{X - E} = ∣∣ f ∣ ∣_{\infty}$ . \end{proof}

8. Let ${f_{n}} \subset L^{1} (μ)$ be nonnegative and satisfying $lim inf_{n} f_{n} \geq f$ a.e. in $X$ . Show that

\int_{X} f_{n} d μ = \int_{X} fd μ = 1 \Rightarrow n lim \int_{X} ∣ f_{n} - f ∣ d μ = 0

(Hint: notice that the positive part and the negative part of $f - f_{n}$ have the same integral to obtain

\int_{X} ∣ f_{n} - f ∣ d μ = 2 \int_{X} (f_{n} - f)^{+} d μ

Then, apply the dominated convergence theorem.)

\begin{proof} Since $\int_{X} f_{n} d μ = \int_{X} fd μ$ , there is

0 = \int_{X} f_{n} - fd μ = \int_{X} (f_{n} - f)^{+} d μ - \int_{X} (f_{n} - f)^{-} d μ

and so $\int_{X} (f_{n} - f)^{+} d μ = \int_{X} (f_{n} - f)^{-} d μ$ . It deduces that $\int_{X} ∣ f_{n} - f ∣ d μ = 2 \int_{X} (f_{n} - f)^{+} d μ$ . Since $lim in f_{n} f_{n} ⩾ f$ a.e. in $X$ , there exists $N$ such that $f_{n} - f ⩾ 0$ almost everywhere when $n ⩾ N$ . Then by DCT, we have $lim_{n} \int_{X} (f_{n} - f)^{+} = 0$ and so for $lim_{n} \int_{X} ∣ f_{n} - f ∣ d μ$ . Now we finish the proof. \end{proof}

9. Show that the following extension of Fatou’s lemma: if $f_{n} \geq - g_{n}$ , with $g_{n} \in L^{1}$ nonnegative, $g_{n} \to g$ in $L^{1}$ , then

n \to \infty lim inf \int_{X} f_{n} d μ \geq \int_{X} n \to \infty lim inf f_{n} d μ

whenever the right hand side is well defined. (Hint: prove first the statement under the additional assumption that $g_{n} \to g$ a.e. in $X$ .)

\begin{proof} Since $f_{n} + g_{n} ⩾ 0$ , by Fatou’s lemma there is

n \to \infty lim inf \int_{X} (f_{n} + g_{n}) d μ ⩾ \int_{X} lim inf (f_{n} + g_{n}) d μ . (*)

To show $lim inf_{n \to \infty} \int_{X} f_{n} d μ \geq \int_{X} lim inf_{n \to \infty} f_{n} d μ$ , it suffices to show $lim inf_{n} \int_{X} g_{n} d μ = \int_{X} lim inf_{n} g_{n} d μ$ . Since $g_{n} \to g$ in $L^{1}$ , we have $\int_{X} ∣ g_{n} - g ∣ d μ \to 0$ as $n \to \infty$ . Note that

0 = n lim \int_{X} ∣ g_{n} - g ∣ d μ ⩾ n lim \int_{X} (g_{n} - g) d μ ⩾ n lim inf \int_{X} g_{n} d μ - \int_{X} g d μ

yields that $lim inf_{n} \int_{X} g_{n} d μ ⩽ \int_{X} lim inf_{n} g_{n} d μ$ . By Fatou’s lemma there is $lim inf_{n} \int_{X} g_{n} d μ ⩾ \int_{X} lim inf_{n} g_{n} d μ$ and so $lim inf_{n} \int_{X} g_{n} d μ ⩽ \int_{X} lim inf_{n} g_{n} d μ$ . Then $(*)$ deduces that $lim inf_{n \to \infty} \int_{X} f_{n} d μ \geq \int_{X} lim inf_{n \to \infty} f_{n} d μ$ . \end{proof}

10. Let ${f_{n}} \subset L^{1} (μ)$ be nonnegative functions. Show that the conditions

n \to \infty lim inf f_{n} \geq f a.e., n \to \infty lim sup \int_{X} f_{n} d μ \leq \int_{X} fd μ < \infty

imply the convergence of $f_{n}$ to $f$ in $L^{1}$ . (Hint: use exercise 8.)

\begin{proof} The conditions and Fatou’s lemma yield that

n lim sup \int_{X} f_{n} d μ ⩽ \int_{X} fd μ ⩽ \int_{X} n lim inf f_{n} d μ ⩽ n lim inf \int_{X} f_{n} d μ .

It follows that $\int_{X} fd μ = lim_{n} \int_{X} f_{n} d μ$ . By exercise 8, we have $lim_{n} \int_{X} ∣ f_{n} - f ∣ d μ = 0$ , that is, $f_{n}$ converges to $f$ in $L^{1}$ . \end{proof}

11. Let $(X, A, μ)$ be a finite measure space. Show that $L^{\infty} \subset L^{p}$ for all $p \in (0, \infty)$ . Also, show that, if $f$ is measurable, then

p \to \infty lim ∥ f ∥_{p} = ∥ f ∥_{\infty}

\begin{proof} To show $L^{\infty} \subseteq L^{p}$ , it suffices to show for any $f$ satisfying $∣∣ f ∣ ∣_{\infty} < \infty$ , there is $∣∣ f ∣ ∣_{p} < \infty$ . By lemma 10.6, $∣ f ∣ ⩽ ∣∣ f ∣ ∣_{\infty}$ a.e., it deduces that

∣∣ f ∣ ∣_{p} = (\int_{X} ∣ f ∣^{p} d μ)^{1/ p} ⩽ (μ (X) ∣∣ f ∣ ∣_{\infty}^{p})^{1/ p} < \infty. (*)

Therefore, $L^{\infty} \subseteq L^{p}$ .

For any simple function $g = \sum_{i = 1}^{n} a_{i} χ_{E_{i}}$ , we have $∣∣ g ∣ ∣_{p} = (\sum_{k = 1}^{n} μ (E_{i}) a_{i}^{p})^{1/ p}$ and $∣∣ g ∣ ∣_{p} \to max_{i} a_{i} = ∣∣ g ∣ ∣_{\infty}$ . Since $f$ is measurable, there exists a sequence of simple functions ${g_{k}}$ such that $∣ g_{k} ∣ ↑ ∣ f ∣$ . Then by MCT we have $lim_{p} ∣∣ f ∣ ∣_{p} = ∣∣ f ∣ ∣_{\infty}$ . \end{proof}

12. Let $0 < p < 1$ and $f, g$ be measurable functions on $X$ such that $f \geq 0, g \geq 0$ . Then

∥ f + g ∥_{p} ⩾ ∥ f ∥_{p} + ∥ g ∥_{p}

(This is Minkowski’s Inequality for $0 < p < 1$ .)

\begin{proof} Let $h (x) = x^{p}$ . Then $h^{''} (x) = p (p - 1) x^{p - 2} < 0$ for any $x > 0$ and $0 < p < 1$ . If one of $∣∣ f ∣ ∣_{p}$ and $∣∣ g ∣ ∣_{p}$ equals $0$ , then $f + g ⩾ f$ and $f + g ⩾ g$ yield that the inequality holds. Now assume that $∣∣ f ∣ ∣_{p} > 0$ and $∣∣ g ∣ ∣_{p} > 0$ .

Define $t = ∣∣ f ∣ ∣_{p} / (∣∣ f ∣ ∣_{p} + ∣∣ g ∣ ∣_{p})$ , then by Jensen’s inequality we have

(f + g)^{p} = (t \cdot \frac{f}{t} + (1 - t) \cdot \frac{g}{1 - t})^{p} ⩾ t (f / t)^{p} + (1 - t) (g / (1 - t))^{p} = t^{1 - p} f^{p} + (1 - t)^{1 - p} g^{p} .

It deduces that $∣∣ f + g ∣ ∣_{p}^{p} ⩾ (∣∣ f ∣ ∣_{p}^{p} + ∣∣ g ∣ ∣_{p}^{p})^{p}$ and so $∥ f + g ∥_{p} ⩾ ∥ f ∥_{p} + ∥ g ∥_{p}$ . \end{proof}

13. a) Let $p \geq 1$ and let $∥ f_{n} - f ∥_{p} \to 0$ as $n \to \infty$ . Show that $∥ f_{n} ∥_{p} \to ∥ f ∥_{p}$ as $n \to \infty$ .

b) Suppose $f_{n}, f \in L^{p}, f_{n} \to f$ a.e and $∥ f_{n} ∥_{p} \to ∥ f ∥_{p}$ as $n \to \infty$ . Show that $∥ f_{n} - f ∥_{p} \to 0$ as $n \to \infty$ .

\begin{proof} a) Note that

- ∣∣ f_{n} - f ∣ ∣_{p} ⩽ ∣∣ f_{n} ∣ ∣_{p} - ∣∣ f ∣ ∣_{p} ⩽ ∣∣ f_{n} - f ∣ ∣_{p}

and $∣∣ f_{n} - f ∣ ∣_{p} \to 0$ , then we have $lim_{n} ∣∣ f_{n} ∣ ∣_{p} = ∣∣ f ∣ ∣_{p}$ by the sandwich theorem.

b) Since $L^{p}$ is a Banach space and $∣ f_{n} ∣, ∣ f ∣ \in L^{p}$ , we have $∣ f_{n} ∣ + ∣ f ∣ \in L^{p}$ . Note that $∣ f_{n} - f ∣^{p} ⩽ (∣ f_{n} ∣ + ∣ f ∣)^{p}$ and $\int_{X} (∣ f_{n} ∣ + ∣ f ∣)^{p} d μ < \infty$ , then by DCT we have

n lim \int_{X} ∣ f_{n} - f ∣^{p} d μ = 0.

Now we finish the proof. \end{proof}

15. Let $p$ and $q$ be conjugate indices and $lim_{n \to \infty} ∥ f_{n} - f ∥_{p} = 0 = lim_{n \to \infty} ∥ g_{n} -$ $g ∥_{q}$ , where $f_{n}, f \in L^{p}$ and $g_{n}, g \in L^{q}, n = 1, 2, \dots$ . Show that $lim_{n \to \infty} ∥ f_{n} g_{n} -$ $f g ∥_{1} = 0$ .

\begin{proof} Note that by the Holder inequality we have

0 ⩽ ∣∣ f_{n} g_{n} - f g ∣ ∣_{1} ⩽ ∣∣ f_{n} g_{n} - f_{n} g ∣ ∣_{1} + ∣∣ f_{n} g - f g ∣ ∣_{1} ⩽ ∣∣ f_{n} ∣ ∣_{p} ∣∣ g_{n} - g ∣ ∣_{q} + ∣∣ f_{n} - f ∣ ∣_{p} ∣∣ g ∣ ∣_{q} \to 0

as $lim_{n} ∣∣ f_{n} - f ∣ ∣_{p} = lim_{n} ∣∣ g_{n} - g ∣ ∣_{q} = 0$ and $∣∣ f_{n} ∣ ∣_{p}, ∣∣ g ∣ ∣_{q} < \infty$ . Therefore, $lim_{n} ∣∣ f_{n} g_{n} - f g ∣ ∣_{1} = 0$ . \end{proof}

17. Let $p, q \in (1, \infty)$ . Show that the inclusion $L^{p} \subset L^{q}$ implies that the inclusion map $i : L^{p} \to L^{q}$ is continuous. (Hint: use closed graph theorem.)

\begin{proof}

Closed graph theorem: if a linear operator between Banach spaces has a closed graph, then the operator is continuous.

By the closed graph theorem, it suffices to show the graph ${(x, x) : x \in L^{p}} \subseteq L^{p} \times L^{q}$ is closed. Suppose ${f_{n}}$ is a sequence in $L^{p}$ and $f_{n} \to f$ in $L^{p}$ , $f_{n} \to g$ in $L^{q}$ . Note that there exists a subsequence $f_{n_{k}}$ such that $f_{n_{k}} \to f$ pointwise a.e. In $L^{q}$ , assume that $i (f_{n_{k}}) = f_{n_{k}} \to g$ in $L^{q}$ . Then there is a subsequence $f_{n_{m_{k}}} \to g$ pointwise a.e. It deduces that $f = g$ a.e. Therefore, ${(f_{n}, f_{n})} \to {(f, f)} \in L^{p} \times L^{q}$ and so ${(x, x) : x \in L^{p}}$ is closed in $L^{p} \times L^{q}$ . By closed graph theorem, $i$ is continuous. \end{proof}

18. Let $(X, A, μ)$ be a finite measure space. Assume that $f \in L^{\infty}, ∥ f ∥_{\infty} > 0$ . Let

a_{n} = \int_{X} ∣ f ∣^{n} d μ, n = 1, \dots .

Prove that

n \to \infty lim \frac{a _{n + 1}}{a _{n}} = ∥ f ∥_{\infty} .

\begin{proof} Note that $a_{n}^{1/ n} = ∣∣ f ∣ ∣_{n}$ for all $n \in N_{+}$ . By exercise 11, we have $lim_{p \to \infty} ∥ f ∥_{p} = ∥ f ∥_{\infty}$ . Then

\frac{a _{n + 1}}{a _{n}} = (\frac{a _{n + 1}^{1/ (n + 1)}}{a _{n}^{1/ n}})^{n} \cdot a_{n + 1}^{1/ (n + 1)} \to ∣∣ f ∣ ∣_{\infty},

because $a_{n}^{1/ n} \to ∣∣ f ∣ ∣_{\infty}$ as $n \to \infty$ . \end{proof}

21. Let $(X, A, μ)$ be a measure space, $2 < p < \infty$ , and ${f_{n}}, f$ defined on $X$ with $∥ f_{n} ∥_{p} \to ∥ f ∥_{p}$ , such that $f_{n} ⇀ f$ in $L^{p}$ . Prove that $f_{n} \to f$ in $L^{p}$ .

\begin{proof} We say $f_{n} ⇀ f$ in $L^{p}$ if for all continuous linear functional $T$ on $L^{p}$ , there is $T (f_{n}) \to T (f)$ as $n \to \infty$ . The following proof is a proof of Radon-Riesz property.

WLOG we assume that $∣∣ f_{n} ∣ ∣_{p} = 1$ , otherwise take $f_{n} = f_{n} /∣∣ f_{n} ∣ ∣_{p}$ . Recall that $L^{p}$ is uniformly convex, then it suffices to show

∣∣ \frac{f _{n} + f}{2} ∣ ∣_{p} \to 1.

Since $T (f_{n}) \to T (f)$ , we have $∣ T (f) ∣ = lim inf_{n} ∣ T (f_{n}) ∣ ⩽ lim inf_{n} ∣∣ T ∣∣∣∣ f_{n} ∣∣$ . Then by $∣∣ f ∣∣ = sup_{T \in (L^{p})^{*}, ∣∣ T ∣∣ = 1} ∣ T (f) ∣$ we have $∣∣ f ∣ ∣_{L^{p}} ⩽ lim inf_{n} ∣∣ f_{n} ∣∣$ . Since $\frac{f _{n} + f}{2} ⇀ f$ , there is

1 = ∣∣ f ∣ ∣_{p} ⩽ n lim inf ∣∣ \frac{f _{n} + f}{2} ∣ ∣_{p} .

Note that $(f_{n} + f) /2$ has norm at most $1$ , then $∣∣ \frac{f _{n} + f}{2} ∣ ∣_{p} \to 1$ and so $∣∣ f_{n} - f ∣ ∣_{p} \to 0$ . \end{proof}

A Banach space $X$ is said to satisfy the Radon-Riesz property (or the Kadec-Klee property) if: A sequence ${x_{n}} \subset X_{converges strongly to x}$ (i.e., $∥ x_{n} - x ∥ \to 0$ ), if and only if:

${x_{n}}$ converges weakly to $x$ , and
$∥ x_{n} ∥ \to ∥ x ∥$ .

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Exercise 9

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