Measure Theory/Outer Measuring Intervals

Template:Robelbox Prove that any singleton set is a null set.

Hint: You may prove this directly as an exercise, but it also follows very trivially from a previous exercise.

Template:Robelbox/close

Now we show that for any closed, bounded interval, ${\displaystyle {\lambda }^{*}([a,b])=b-a}$. As is typical with proofs in analysis, we do this by showing two inequalities.

The first inequality that we will show is ${\displaystyle {\lambda }^{*}([a,b])\le b-a}$.

We can accomplish this by observing that for any ${\displaystyle \epsilon \in {ℝ}^{+}}$ the set ${\displaystyle \{(a-\epsilon ,b+\epsilon )\}}$ is always an open interval over-approximation.

The corresponding over-estimate is ${\displaystyle b-a+2\epsilon }$. Template:Robelbox Complete the argument that, due to what we have seen above, ${\displaystyle {\lambda }^{*}([a,b])\le b-a}$.

Template:Robelbox/close

In order to show ${\displaystyle b-a\le {\lambda }^{*}([a,b])}$, we will show that ${\displaystyle b-a}$ is a lower bound on the set of over-estimates. Recall that, by definition, ${\displaystyle {\lambda }^{*}([a,b])}$ is the greatest of all such lower bounds.

To this end we let ${\displaystyle 𝔒}$ be any open interval over-approximation of ${\displaystyle [a,b]}$. Let ${\displaystyle e=\sum _{I\in 𝔒}\ell (I)}$ be the corresponding over-estimate.

Because ${\displaystyle [a,b]}$ is compact, and because ${\displaystyle 𝔒}$ is an open cover, then there must exist a finite subcover, ${\displaystyle {𝔒}^{\prime }\subseteq 𝔒}$. Let ${\displaystyle e^{\prime }}$ be its corresponding over-estimate.

Notice that every term which makes up e' also occurs in e. Therefore ${\displaystyle e^{\prime }\le e}$.

Further, it will be useful if no interval in ${\displaystyle {𝔒}^{\prime }}$ is a subset of any other interval in it. Therefore we may construct a still smaller approximation, ${\displaystyle {𝔒}^{″}}$ which results from removing intervals from ${\displaystyle {𝔒}^{\prime }}$ until no interval that remains is a subset of any other interval in ${\displaystyle {𝔒}^{″}}$. Template:Robelbox Prove that ${\displaystyle {𝔒}^{″}}$ constructed above is still an open interval over-approximation of ${\displaystyle [a,b]}$.

Template:Robelbox/close Let ${\displaystyle e^{″}}$ be the over-estimate corresponding to ${\displaystyle {𝔒}^{″}}$. As before, we have ${\displaystyle e^{″}\le e^{\prime }}$.

Now assume that ${\displaystyle {𝔒}^{″}=\{(a_1,b_1),(a_2,b_2),\dots ,(a_n,b_n)\}}$ and assume that these intervals are listed "in order". Here "in order" means that ${\displaystyle a_1<a_2<\cdots <a_n}$. Template:Robelbox

1. Prove that, with the ordering given above for the intervals, ${\displaystyle a_i<b_{i-1}}$ for each ${\displaystyle 2\le i\le n}$.  Hint: If this were not true, you would get an interval inside another interval in ${\displaystyle {𝔒}^{″}}$.

Further show that ${\displaystyle a_1<a}$ and ${\displaystyle b<b_n}$.  

2. Show that ${\displaystyle e^{″}=b_n-a_1+{\displaystyle \sum _{i=2}^n}(b_{i-1}-a_i)}$.  Hint: Write out the definition of ${\displaystyle e^{″}}$ as a sum and rearrange the terms.  It may help to not use sigma-notation for the summation, in order to see how to do the rearrangement.  

Infer, with the help of (1.), that ${\displaystyle e^{″}\ge b-a}$.

Reason through the remainder of the proof.

Template:Robelbox/close Template:Robelbox Use the result above to prove that the outer measure of any open interval also equals its length.

Hint: Start with a bounded open interval, (a,b). Approximate this "from below" with intervals of the form ${\displaystyle [a+\epsilon ,b-\epsilon ]}$ and then use monotonicity to prove ${\displaystyle b-a-2\epsilon \le {\lambda }^{*}((a,b))}$. Then let ${\displaystyle \epsilon \to 0}$.

The reverse inequality should be even more direct.

The use of monotonicity and the outer measure of closed intervals, gives an easy proof that ${\displaystyle {\lambda }^{*}(I)=\mathrm{\infty }}$ if I is an unbounded interval. Template:Robelbox/close

Template:CourseCat