Vitali–Hahn–Saks theorem

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In mathematics, the Vitali–Hahn–Saks theorem, introduced by Vitali (1907), Hahn (1922), and Saks (1933), proves that under some conditions a sequence of measures converging point-wise does so uniformly and the limit is also a measure.

Statement of the theorem

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If   is a measure space with   and a sequence   of complex measures. Assuming that each   is absolutely continuous with respect to   and that a for all   the finite limits exist   Then the absolute continuity of the   with respect to   is uniform in   that is,   implies that   uniformly in   Also   is countably additive on  

Preliminaries

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Given a measure space   a distance can be constructed on   the set of measurable sets   with   This is done by defining

  where   is the symmetric difference of the sets  

This gives rise to a metric space   by identifying two sets   when   Thus a point   with representative   is the set of all   such that  

Proposition:   with the metric defined above is a complete metric space.

Proof: Let   Then   This means that the metric space   can be identified with a subset of the Banach space  .

Let  , with   Then we can choose a sub-sequence   such that   exists almost everywhere and  . It follows that   for some   (furthermore   if and only if   for   large enough, then we have that   the limit inferior of the sequence) and hence   Therefore,   is complete.

Proof of Vitali-Hahn-Saks theorem

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Each   defines a function   on   by taking  . This function is well defined, this is it is independent on the representative   of the class   due to the absolute continuity of   with respect to  . Moreover   is continuous.

For every   the set   is closed in  , and by the hypothesis   we have that   By Baire category theorem at least one   must contain a non-empty open set of  . This means that there is   and a   such that   implies   On the other hand, any   with   can be represented as   with   and  . This can be done, for example by taking   and  . Thus, if   and   then   Therefore, by the absolute continuity of   with respect to  , and since   is arbitrary, we get that   implies   uniformly in   In particular,   implies  

By the additivity of the limit it follows that   is finitely-additive. Then, since   it follows that   is actually countably additive.

References

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  • Hahn, H. (1922), "Über Folgen linearer Operationen", Monatsh. Math. (in German), 32: 3–88, doi:10.1007/bf01696876
  • Saks, Stanislaw (1933), "Addition to the Note on Some Functionals", Transactions of the American Mathematical Society, 35 (4): 965–970, doi:10.2307/1989603, JSTOR 1989603
  • Vitali, G. (1907), "Sull' integrazione per serie", Rendiconti del Circolo Matematico di Palermo (in Italian), 23: 137–155, doi:10.1007/BF03013514
  • Yosida, K. (1971), Functional Analysis, Springer, pp. 70–71, ISBN 0-387-05506-1