Kuratowski's intersection theorem

In mathematics, Kuratowski's intersection theorem is a result in general topology that gives a sufficient condition for a nested sequence of sets to have a non-empty intersection. Kuratowski's result is a generalisation of Cantor's intersection theorem. Whereas Cantor's result requires that the sets involved be compact, Kuratowski's result allows them to be non-compact, but insists that their non-compactness “tends to zero” in an appropriate sense. The theorem is named for the Polish mathematician Kazimierz Kuratowski, who proved it in 1930.

Let (X, d) be a complete metric space. Given a subset A ⊆ X, its Kuratowski measure of non-compactness α(A) ≥ 0 is defined by

${\displaystyle \alpha (A)=\inf \left\{r\geq 0\left|{\begin{array}{c}A{\text{ can be covered by finitely many subsets}}\\{\text{of }}X{\text{, each with diameter at most }}r\end{array}}\right.\right\}.}$

Note that, if A is itself compact, then α(A) = 0, since every cover of A by open balls of arbitrarily small diameter will have a finite subcover. The converse is also true: if α(A) = 0, then A must be precompact, and indeed compact if A is closed. Also, if A is a subset of B, then α(A) ≤ α(B). In some sense, the quantity α(A) is a numerical description of “how non-compact” the set A is.

Now consider a sequence of sets A_n ⊆ X, one for each natural number n. Kuratowski's intersection theorem asserts that if these sets are non-empty, closed, decreasingly nested (i.e. A_n+1 ⊆ A_n for each n), and α(A_n) → 0 as n → ∞, then their infinite intersection

${\displaystyle \bigcap _{n\in \mathbb {N} }A_{n}}$

is a non-empty compact set.

• Kuratowski, Kazimierz (1930). "Sur les espaces complets". Fundamenta Mathematicae. 15: 301–309. doi:10.4064/fm-15-1-301-309.