Measure Theory, Problem Set 2

Integration: Exercises

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updates: 8 March 2011

Measure Theory Problem Set 2

Let $(X, Σ)$ be a measure space. Let $f, g : X \to ℝ$ be measurable. Let $ε > 0$ . Show that the set ${x \in X | f (x) + ε < g (x)}$ is in $Σ$ .
Let $(X, Σ)$ be a measure space and let $μ : Σ \to [0, \infty]$ be a measure.

(i) For $h : X \to ℝ$ a simple function, give the definition of $\int h d μ$ .

(ii) Let $f : X \to ℝ_{\geq 0}$ be integrable. Give the definition of $\int h d μ$ .

(iii) Working directly from the definition of the integral show that if $g : X \to ℝ$ is defined by $g (x) = 3 f (x)$ then $\int g d μ = 3 \int f d μ$ .
Let $K$ be a compact subset of $ℝ$ . Let $f : K \to ℝ$ be continuous. Let $ε > 0$ . Show that there exist $n \in ℤ_{\geq 0}$ and $a_{0}, a_{1}, \dots, a_{n} \in ℝ$ such that for all $x \in K$ , $| f (x) - (a_{0} + a_{1} x + a_{2} x^{2} + \dots + a_{n} x^{n}) | < ε .$
Show that if $μ, ν$ are Borel probability measures on a standard Borel space then we can find (positive) $μ_{0}, μ_{1}$ with $μ = μ_{0} + μ_{1} μ_{0} ≪ ν, μ_{1} ⊥ ν .$
Let $m^{*}$ be the outer measure used to define Lebesgue measure $m$ . Carefully define $m^{*}$ and Lebesgue measurable sets. Show that if $B \subseteq ℝ$ is Lebesgue measurable then there are Borel $A_{1}, A_{2} \subseteq ℝ$ with $A_{1} \subseteq B \subseteq A_{2}$ and $m (A_{2} \ A_{1}) = 0$ .
Let $Σ_{0} \subseteq Σ_{1}$ be two σ-algebras on a set $X$ . Let $μ$ be a σ-finite measure on $(X, Σ_{1})$ and let $f : X \to ℝ$ be measurable with respect to $Σ_{1}$ . Show that there is a function $g : X \to ℝ$ which is measurable with respect to $Σ_{0}$ such that on any $B \in Σ_{0}$ $\int_{B} g (x) d μ (x) = \int_{B} f (x) d μ (x)$
Let $Y$ be a standard Borel space and let $μ$ be a finite atomless Borel measure on $Y$ . Then for all $c \in ℝ$ with $0 \leq c \leq μ (Y)$ , we can find $B \subseteq Y$ with $μ (B) = c$ .
Show that there exists a subset $V \subseteq [0, 1]$ which is not Lebesgue measurable.
Let $K$ be a compact metric space. Let $A \subseteq K$ be Borel. Let $ν_{1}, ν_{2}$ be finite Borel measures on $K$ with the property that $ν_{1} (B) = 0$ for all Borel $B \subseteq A^{c}$ , and $ν_{2} (B) = 0$ for all Borel $B \subseteq A$ . Let $μ$ be the signed measure $ν_{1} - ν_{2}$ (i.e. $μ (B) = ν_{1} (B) - ν_{2} (B)$ ). Show that $ν_{1} (A) + ν_{2} (A^{c})$ equals the supremum of ${| \int f d μ | | f : K \to [-1, 1] is continuous} .$
Let $K = [0, 1]$ , the unit interval in its usual topology. Let $P (K)$ be the space of probability measures on $K$ equipped with the topology generated by the basic open sets ${μ \in P (K) | \int f_{1} d μ \in (a_{1}, b_{1}), \int f_{2} d μ \in (a_{2}, b_{2}), \dots, \int f_{n} d μ \in (a_{n}, b_{n})},$ for $n \in ℤ_{> 0}$ , $f_{1}, \dots, f_{n}$ continuous functions from $K$ to $ℝ$ , and $a_{1}, b_{1}, \dots, a_{n}, b_{n} \in ℝ$ . Let $U$ be the open interval $(0, \frac{1}{2})$ . Is $A = {μ \in P (K) | μ (U) = 1}$ closed in this topology?
Let $(X, Σ)$ be a finite measure space. Let ${(f_{n})}_{n \in ℤ_{> 0}}$ be a sequence of measurable functions which converge pointwise to $f$ . Then for any $ε > 0$ there is $A \in Σ$ with $μ (X \ A) < ε$ and $(f_{n})$ converging uniformly to $f$ on $A$ .
Equip ${H, T}$ with the discrete topology and let $\prod_{ℤ_{> 0}} {H, T}$ be the collection of all functions $f : ℤ_{> 0} \to {H, T}$ equipped with the product topology. For $\vec{i} = (i_{1}, i_{2}, \dots i_{N})$ a sequence of distinct elements of $ℤ_{> 0}$ and $\vec{S} = (S_{1}, S_{2}, \dots, S_{N})$ a sequence of elements of ${H, T}$ let $A_{\vec{i}, \vec{S}} = {f \in \prod_{ℤ_{> 0}} | f (i_{1}) = S_{1}, f (i_{2}) = S_{2}, \dots, f (i_{N}) = S_{N}} .$ Let $Σ_{0}$ be the collection of all finite unions of the sets of the form $A_{\vec{i}, \vec{S}}$ . Define $μ_{0} : {A_{\vec{i}, \vec{S}}} \to ℝ_{\geq 0}$ by $μ_{0} (A_{\vec{i}, \vec{S}}) = 2^{- N}$ . Show that $μ_{0}$ extends to a function on $Σ_{0}$ which is σ-additive on its domain.

Notes and References

These exercises are taken from problems by G. Hjorth for a course in "Measure Theory" at the Masters level at University of Melbourne.

References

[Ru] W. Rudin, Real and complex analysis, Third edition, McGraw-Hill, 1987. MR??????.

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