Lebesgue's number lemma

The printable version is no longer supported and may have rendering errors. Please update your browser bookmarks and please use the default browser print function instead.

In topology, the Delta number, is a useful tool in the study of compact metric spaces. It states:

If the metric space

(X,d)

is compact and an open cover of

X

is given, then there exists a number

\delta >0

such that every subset of

X

having diameter less than

\delta

is contained in some member of the cover.

Such a number $\delta$ is called a Delta number of this cover. The notion of a Delta number itself is useful in other applications as well.

Proof

Direct Proof

Let ${\mathcal {U}}$ be an open cover of $X$ . Since $X$ is compact we can extract a finite subcover $\{A_{1},\dots ,A_{n}\}\subseteq {\mathcal {U}}$ . If any one of the $A_{i}$ 's equals $X$ then any $\delta >0$ will serve as a Delta number. Otherwise for each $i\in \{1,\dots ,n\}$ , let $C_{i}:=X\smallsetminus A_{i}$ , note that $C_{i}$ is not empty, and define a function $f:X\rightarrow \mathbb {R}$ by

f(x):={\frac {1}{n}}\sum _{i=1}^{n}d(x,C_{i}).

Since $f$ is continuous on a compact set, it attains a minimum $\delta$ . The key observation is that, since every $x$ is contained in some $A_{i}$ , the extreme value theorem shows $\delta >0$ . Now we can verify that this $\delta$ is the desired Delta number. If $Y$ is a subset of $X$ of diameter less than $\delta$ , choose $x_{0}$ as any point in $Y$ , then by definition of diameter, $Y\subseteq B_{\delta }(x_{0})$ , where $B_{\delta }(x_{0})$ denotes the ball of radius $\delta$ centered at $x_{0}$ . Since $f(x_{0})\geq \delta$ there must exist at least one $i$ such that $d(x_{0},C_{i})\geq \delta$ . But this means that $B_{\delta }(x_{0})\subseteq A_{i}$ and so, in particular, $Y\subseteq A_{i}$ .

Proof by Contradiction

Suppose for contradiction that that $X$ is sequentially compact, $\{U_{\alpha }\mid \alpha \in J\}$ is an open cover of $X$ , and the Lebesgue number $\delta$ does not exist. That is: for all $\delta >0$ , there exists $A\subset X$ with $\operatorname {diam} (A)<\delta$ such that there does not exist $\beta \in J$ with $A\subset U_{\beta }$ .

This enables us to perform the following construction:

\delta _{1}=1,\quad \exists A_{1}\subset X\quad {\text{where}}\quad \operatorname {diam} (A_{1})<\delta _{1}\quad {\text{and}}\quad \neg \exists \beta (A_{1}\subset U_{\beta })

\delta _{2}={\frac {1}{2}},\quad \exists A_{2}\subset X\quad {\text{where}}\quad \operatorname {diam} (A_{2})<\delta _{2}\quad {\text{and}}\quad \neg \exists \beta (A_{2}\subset U_{\beta })

\vdots

\delta _{k}={\frac {1}{k}},\quad \exists A_{k}\subset X\quad {\text{where}}\quad \operatorname {diam} (A_{k})<\delta _{k}\quad {\text{and}}\quad \neg \exists \beta (A_{k}\subset U_{\beta })

\vdots

Note that $A_{n}\neq \emptyset$ for all $n\in \mathbb {Z} ^{+}$ , since $A_{n}\not \subset U_{\beta }$ . It is therefore possible by the axiom of choice to construct a sequence $(x_{n})$ in which $x_{i}\in A_{i}$ for each $i$ . Since $X$ is sequentially compact, there exists a subsequence $\{x_{n_{k}}\}$ (with $k\in \mathbb {Z} _{>0}$ ) that converges to $x_{0}$ .

Because $\{U_{\alpha }\}$ is an open cover, there exists some $\alpha _{0}\in J$ such that $x_{0}\in U_{\alpha _{0}}$ . As $U_{\alpha _{0}}$ is open, there exists $r>0$ with $B_{d}(x_{0},r)\subset U_{\alpha _{0}}$ . Now we invoke the convergence of the subsequence $\{x_{n_{k}}\}$ : there exists $L\in \mathbb {Z} ^{+}$ such that $L\leq k$ implies $x_{n_{k}}\in B_{r/2}(x_{0})$ .

Furthermore, there exists $M\in \mathbb {Z} _{>0}$ such that $\delta _{M}={\tfrac {1}{M}}<{\tfrac {r}{2}}$ . Hence for all $z\in \mathbb {Z} _{>0}$ , we have $M\leq z$ implies $\operatorname {diam} (A_{M})<{\tfrac {r}{2}}$ .

Finally, define $q\in \mathbb {Z} _{>0}$ such that $n_{q}\geq M$ and $q\geq L$ . For all $x'\in A_{n_{q}}$ , notice that:

$d(x_{n_{q}},x')\leq \operatorname {diam} (A_{n_{q}})<{\frac {r}{2}}$ , because $n_{q}\geq M$ .
$d(x_{n_{q}},x_{0})<{\frac {r}{2}}$ , because $q\geq L$ entails $x_{n_{q}}\in B_{r/2}\left(x_{0}\right)$ .