User:IssaRice/Taking inf and sup separately: Difference between revisions

This page describes a trick that is sometimes helpful in analysis.

Satement

Let ${\displaystyle A}$ and ${\displaystyle B}$ be bounded subsets of the real line. Suppose that for every ${\displaystyle a\in A}$ and ${\displaystyle b\in B}$ we have ${\displaystyle a\ge b}$. Then ${\displaystyle inf(A)\ge sup(B)}$.

Actually, do ${\displaystyle A}$ and ${\displaystyle B}$ have to be bounded? I think they can even be empty!

Proof

Let ${\displaystyle a\in A}$ and ${\displaystyle b\in B}$ be arbitrary. We have by hypothesis ${\displaystyle a\ge b}$. Since ${\displaystyle b}$ is arbitrary, we have that ${\displaystyle a}$ is an upper bound of the set ${\displaystyle B}$, so taking the superemum over ${\displaystyle b}$ we have ${\displaystyle a\ge sup(B)}$ (remember, ${\displaystyle sup(B)}$ is the least upper bound, whereas ${\displaystyle a}$ is just another upper bound). Since ${\displaystyle a}$ was arbitrary, we see that ${\displaystyle sup(B)}$ is a lower bound of the set ${\displaystyle A}$. Taking the infimum over ${\displaystyle a}$, we have ${\displaystyle inf(A)\ge sup(B)}$, as required.

Applications

liminf vs limsup

(Notation from Tao's Analysis I.)

Let ${\displaystyle (a_n{)}_{n=m}^{\mathrm{\infty }}}$ be a sequence of real numbers. Let ${\displaystyle L^{-}:={lim inf}_{n\to \mathrm{\infty }}{a}_n}$ and let ${\displaystyle L^{+}:={lim sup}_{n\to \mathrm{\infty }}{a}_n}$. Then we have ${\displaystyle L^{-}\le L^{+}}$.

Consider the sequences ${\displaystyle (a_N^{-}{)}_{N=m}^{\mathrm{\infty }}}$ and ${\displaystyle (a_N^{+}{)}_{N=m}^{\mathrm{\infty }}}$ defined by ${\displaystyle a_N^{-}:=inf(a_n{)}_{n=N}^{\mathrm{\infty }}}$ and ${\displaystyle a_N^{+}:=sup(a_n{)}_{n=N}^{\mathrm{\infty }}}$.

Now consider the sets ${\displaystyle A:=\{a_N^{+}:N\ge m\}}$ and ${\displaystyle B:=\{a_N^{-}:N\ge m\}}$. If we can show that ${\displaystyle a_j^{+}\ge a_k^{-}}$ for arbitrary ${\displaystyle j,k\ge m}$, then we can apply the trick to these sets to conclude that ${\displaystyle L^{+}=inf(a_N^{+}{)}_{N=m}=inf(A)\ge sup(B)=sup(a_N^{-}{)}_{N=m}=L^{-}}$.

Lower and upper Riemann integral

(Notation from Tao's Analysis I.)

Let ${\displaystyle I}$ be a bounded interval on the real line, and let ${\displaystyle f:I\to \mathbf{R}}$.

We have

${\displaystyle {\overline{\int }}_{I}f:=inf\{p.c.{\int }_{I}g:g\text{ is a p.c. function on }I\text{ that majorizes }f\}}$

${\displaystyle {\underset{\_}{\int }}_{I}f:=sup\{p.c.{\int }_{I}g:g\text{ is a p.c. function on }I\text{ that minorizes }f\}}$

We want to show ${\displaystyle {\underset{\_}{\int }}_{I}f\le {\overline{\int }}_{I}f}$.

Define

${\displaystyle A:=\{p.c.{\int }_{I}g:g\text{ is a p.c. function on }I\text{ that majorizes }f\}}$

${\displaystyle B:=\{p.c.{\int }_{I}g:g\text{ is a p.c. function on }I\text{ that minorizes }f\}}$

Then we have ${\displaystyle {\overline{\int }}_{I}f=inf(A)}$ and ${\displaystyle {\underset{\_}{\int }}_{I}f=sup(B)}$. To apply the trick all we need to do is to let ${\displaystyle g}$ be a p.c. function on ${\displaystyle I}$ that majorizes ${\displaystyle f}$, and let ${\displaystyle h}$ be a p.c. function on ${\displaystyle I}$ that minorizes ${\displaystyle f}$, and show that ${\displaystyle p.c.{\int }_{I}g\ge p.c.{\int }_{I}h}$.

References

After I wrote this page, I found the same theorem in Apostol's Calculus (volume 1, 2nd edition, p. 28) in the section "Fundamental properties of the supremum and infimum".