Differentiation of integrals


In mathematics, the problem of differentiation of integrals is that of determining under what circumstances the mean value integral of a suitable function on a small neighbourhood of a point approximates the value of the function at that point. More formally, given a space X with a measure μ and a metric d, one asks for what functions f : XR does
for all xX? 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 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-dimensional Lebesgue measure λn on n-dimensional Euclidean space Rn. Then, for any locally integrable function f : RnR, one has
for λn-almost all points xRn. It is important to note, however, that the measure zero set of "bad" points depends on the function f.

Borel measures on R''n''

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 μ is any locally finite Borel measure on Rn and f : RnR is locally integrable with respect to μ, then
for μ-almost all points xRn.

Gaussian measures

The problem of the differentiation of integrals is much harder in an infinite-dimensional setting. Consider a separable Hilbert space equipped with a Gaussian measure γ. 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 show the kind of difficulties that one can expect to encounter in this setting:
However, there is some hope if one has good control over the covariance of γ. Let the covariance operator of γ be S : HH given by
or, for some countable orthonormal basis iN of H,
In 1981, Preiss and Jaroslav Tišer showed that if there exists a constant 0 < q < 1 such that
then, for all fL1,
where the convergence is convergence in measure with respect to γ. In 1988, Tišer showed that if
for some α > 5 ⁄ 2, then
for γ-almost all x and all fLp, p > 1.
As of 2007, it is still an open question whether there exists an infinite-dimensional Gaussian measure γ on a separable Hilbert space H so that, for all fL1,
for γ-almost all xH. However, it is conjectured that no such measure exists, since the σi would have to decay very rapidly.