Richardson's theorem: Difference between revisions

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In [[mathematics]], the problem of '''differentiation of integrals''' is that of determining under what circumstances the [[average|mean value]] [[integral]] of a suitable [[function (mathematics)|function]] on a small [[neighbourhood (topology)|neighbourhood]] of a point approximates the value of the function at that point.  More formally, given a space ''X'' with a [[measure (mathematics)|measure]] ''μ'' and a [[metric space|metric]] ''d'', one asks for what functions ''f'' : ''X'' → '''R''' does
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:<math>\lim_{r \to 0} \frac1{\mu \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \mu(y) = f(x)</math>
 
for all (or at least ''&mu;''-[[almost all]]) ''x''&nbsp;&isin;&nbsp;''X''?  (Here, as in the rest of the article, ''B''<sub>''r''</sub>(''x'') denotes the [[open ball]] in ''X'' with ''d''-[[radius]] ''r'' and centre ''x''.)  This is a natural question to ask, especially in view of the heuristic construction of the [[Riemann integral]], in which it is almost implicit that ''f''(''x'') is a "good representative" for the values of ''f'' near ''x''.
 
==Theorems on the differentiation of integrals==
 
===Lebesgue measure===
 
One result on the differentiation of integrals is the [[Lebesgue differentiation theorem]], as proved by [[Henri Lebesgue]] in 1910. Consider ''n''-[[dimension]]al [[Lebesgue measure]] ''&lambda;''<sup>''n''</sup> on ''n''-dimensional [[Euclidean space]] '''R'''<sup>''n''</sup>.  Then, for any [[locally integrable function]] ''f''&nbsp;:&nbsp;'''R'''<sup>''n''</sup>&nbsp;&rarr;&nbsp;'''R''', one has
 
:<math>\lim_{r \to 0} \frac1{\lambda^{n} \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \lambda^{n} (y) = f(x)</math>
 
for ''&lambda;''<sup>''n''</sup>-almost all points ''x''&nbsp;&isin;&nbsp;'''R'''<sup>''n''</sup>.  It is important to note, however, that the measure zero set of "bad" points depends on the function ''f''.
 
===Borel measures on '''R'''<sup>''n''</sup>===
 
The result for Lebesgue measure turns out to be a special case of the following result, which is based on the [[Besicovitch covering theorem]]: if ''&mu;'' is any [[locally finite measure|locally finite]] [[Borel measure]] on '''R'''<sup>''n''</sup> and ''f''&nbsp;:&nbsp;'''R'''<sup>''n''</sup>&nbsp;&rarr;&nbsp;'''R''' is locally integrable with respect to ''&mu;'', then
 
:<math>\lim_{r \to 0} \frac1{\mu \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \mu (y) = f(x)</math>
 
for ''&mu;''-almost all points ''x''&nbsp;&isin;&nbsp;'''R'''<sup>''n''</sup>.
 
===Gaussian measures===
 
The problem of the differentiation of integrals is much harder in an infinite-dimensional setting.  Consider a [[separable space|separable]] [[Hilbert space]] (''H'',&nbsp;&lang;&nbsp;,&nbsp;&rang;) equipped with a [[Gaussian measure]] ''&gamma;''.  As stated in the article on the [[Vitali covering theorem]], the Vitali covering theorem fails for Gaussian measures on infinite-dimensional Hilbert spaces.  Two results of David Preiss (1981 and 1983) show the kind of difficulties that one can expect to encounter in this setting:
* There is a Gaussian measure ''&gamma;'' on a separable Hilbert space ''H'' and a Borel set ''M''&nbsp;&sube;&nbsp;''H'' so that, for ''&gamma;''-almost all ''x''&nbsp;&isin;&nbsp;''H'',
::<math>\lim_{r \to 0} \frac{\gamma \big( M \cap B_{r} (x) \big)}{\gamma \big( B_{r} (x) \big)} = 1.</math>
* There is a Gaussian measure ''&gamma;'' on a separable Hilbert space ''H'' and a function ''f''&nbsp;&isin;&nbsp;''L''<sup>1</sup>(''H'',&nbsp;''&gamma;'';&nbsp;'''R''') such that
::<math>\lim_{r \to 0} \inf \left\{ \left. \frac1{\gamma \big( B_{s} (x) \big)} \int_{B_{s} (x)} f(y) \, \mathrm{d} \gamma(y) \right| x \in H, 0 < s < r \right\} = + \infty.</math>
 
However, there is some hope if one has good control over the [[covariance]] of ''&gamma;''. Let the covariance operator of ''&gamma;'' be ''S''&nbsp;:&nbsp;''H''&nbsp;&rarr;&nbsp;''H'' given by
 
:<math>\langle Sx, y \rangle = \int_{H} \langle x, z \rangle \langle y, z \rangle \, \mathrm{d} \gamma(z),</math>
 
or, for some [[countable set|countable]] [[orthonormal basis]] (''e''<sub>''i''</sub>)<sub>''i''&isin;'''N'''</sub> of ''H'',
 
:<math>Sx = \sum_{i \in \mathbf{N}} \sigma_{i}^{2} \langle x, e_{i} \rangle e_{i}.</math>
 
In 1981, Preiss and Jaroslav Tišer showed that if there exists a constant 0&nbsp;&lt;&nbsp;''q''&nbsp;&lt;&nbsp;1 such that
 
:<math>\sigma_{i + 1}^{2} \leq q \sigma_{i}^{2},</math>
 
then, for all ''f''&nbsp;&isin;&nbsp;''L''<sup>1</sup>(''H'',&nbsp;''&gamma;'';&nbsp;'''R'''),
 
:<math>\frac1{\mu \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \mu(y) \xrightarrow[r \to 0]{\gamma} f(x),</math>
 
where the convergence is [[convergence in measure]] with respect to ''&gamma;''. In 1988, Tišer showed that if
 
:<math>\sigma_{i + 1}^{2} \leq \frac{\sigma_{i}^{2}}{i^{\alpha}}</math>
 
for some ''&alpha;''&nbsp;&gt;&nbsp;5&nbsp;&frasl;&nbsp;2, then
 
:<math>\frac1{\mu \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \mu(y) \xrightarrow[r \to 0]{} f(x),</math>
 
for ''&gamma;''-almost all ''x'' and all ''f''&nbsp;&isin;&nbsp;''L''<sup>''p''</sup>(''H'',&nbsp;''&gamma;'';&nbsp;'''R'''), ''p''&nbsp;&gt;&nbsp;1.
 
As of 2007, it is still an open question whether there exists an infinite-dimensional Gaussian measure ''&gamma;'' on a separable Hilbert space ''H'' so that, for all ''f''&nbsp;&isin;&nbsp;''L''<sup>1</sup>(''H'',&nbsp;''&gamma;'';&nbsp;'''R'''),
 
:<math>\lim_{r \to 0} \frac1{\gamma \big( B_{r} (x) \big)} \int_{B_{r} (x)} f(y) \, \mathrm{d} \gamma(y) = f(x)</math>
 
for ''&gamma;''-almost all ''x''&nbsp;&isin;&nbsp;''H''. However, it is conjectured that no such measure exists, since the ''&sigma;''<sub>''i''</sub> would have to decay very rapidly.
 
==See also==
* [[Differentiation under the integral sign]]
 
==References==
 
* {{cite book
| last = Preiss
| first = David
| coauthors = Tišer, Jaroslav
| chapter = Differentiation of measures on Hilbert spaces
| title = Measure theory, Oberwolfach 1981 (Oberwolfach, 1981)
| series = Lecture Notes in Math.
| volume = 945
| pages = 194&ndash;207
| publisher = Springer
| location = Berlin
| year = 1982
}} {{MathSciNet|id=675283}}
* {{cite journal
| last = Tišer
| first = Jaroslav
| title = Differentiation theorem for Gaussian measures on Hilbert space
| journal = Trans. Amer. Math. Soc.
| volume = 308
| year = 1988
| issue = 2
| pages = 655&ndash;666
| doi = 10.2307/2001096
| publisher = Transactions of the American Mathematical Society, Vol. 308, No. 2
| jstor = 2001096
}} {{MathSciNet|id=951621}}
 
[[Category:Theorems in analysis]]
[[Category:Measure theory]]

Latest revision as of 15:30, 2 December 2014

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