Blaschke selection theorem

The Blaschke selection theorem is a result in topology and convex geometry about sequences of convex sets. Specifically, given a sequence $\{K_{n}\}$ of convex sets contained in a bounded set, the theorem guarantees the existence of a subsequence $\{K_{{n_{m}}}\}$ and a convex set $K$ such that $K_{{n_{m}}}$ converges to $K$ in the Hausdorff metric. The theorem is named for Wilhelm Blaschke.

Alternate statements

A succinct statement of the theorem is that a metric space of convex bodies is locally compact.
Using the Hausdorff metric on sets, every infinite collection of compact subsets of the unit ball has a limit point (and that limit point is itself a compact set).

Application

As an example of its use, the isoperimetric problem can be shown to have a solution.^[1] That is, there exists a curve of fixed length that encloses the maximum area possible. Other problems likewise can be shown to have a solution:

Lebesgue's universal covering problem for a convex universal cover of minimal size for the collection of all sets in the plane of unit diameter,^[1]
the maximum inclusion problem,^[1]
and the Moser's worm problem for a convex universal cover of minimal size for the collection of planar curves of unit length.^[2]

Notes

1 2 3 Paul J. Kelly; Max L. Weiss (1979). Geometry and Convexity: A Study in Mathematical Methods. Wiley. pp. Section 6.4.
↑ Wetzel, John E. (July 2005). "The Classical Worm Problem --- A Status Report". Geombinatorics. 15 (1): 34–42.

References

A. B. Ivanov (2001) [1994], "Blaschke selection theorem", in Hazewinkel, Michiel, Encyclopedia of Mathematics, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4
V. A. Zalgaller (2001) [1994], "Metric space of convex sets", in Hazewinkel, Michiel, Encyclopedia of Mathematics, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4
Kai-Seng Chou; Xi-Ping Zhu (2001). The Curve Shortening Problem. CRC Press. p. 45. ISBN 1-58488-213-1.

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[KellyWeiss-1] 1 2 3 Paul J. Kelly; Max L. Weiss (1979). Geometry and Convexity: A Study in Mathematical Methods. Wiley. pp. Section 6.4.

[2] Wetzel, John E. (July 2005). "The Classical Worm Problem --- A Status Report". Geombinatorics. 15 (1): 34–42.