Vitali convergence theorem

Last updated November 21, 2024

In real analysis and measure theory, the Vitali convergence theorem, named after the Italian mathematician Giuseppe Vitali, is a generalization of the better-known dominated convergence theorem of Henri Lebesgue. It is a characterization of the convergence in L^p in terms of convergence in measure and a condition related to uniform integrability.

Preliminary definitions

Let $(X,{\mathcal {A}},\mu )$ be a measure space, i.e. ${\displaystyle \mu$ is a set function such that $\mu (\emptyset )=0$ and $\mu$ is countably-additive. All functions considered in the sequel will be functions $f:X\to \mathbb {K}$ , where $\mathbb {K} =\mathbb {R}$ or $\mathbb {C}$ . We adopt the following definitions according to Bogachev's terminology.^[1]

A set of functions ${\mathcal {F}}\subset L^{1}(X,{\mathcal {A}},\mu )$ is called uniformly integrable if $\lim _{M\to +\infty }\sup _{f\in {\mathcal {F}}}\int _{\{|f|>M\}}|f|\,d\mu =0$ , i.e $\forall \ \varepsilon >0,\ \exists \ M_{\varepsilon }>0:\sup _{f\in {\mathcal {F}}}\int _{\{|f|\geq M_{\varepsilon }\}}|f|\,d\mu <\varepsilon$ .
A set of functions ${\mathcal {F}}\subset L^{1}(X,{\mathcal {A}},\mu )$ is said to have uniformly absolutely continuous integrals if $\lim _{\mu (A)\to 0}\sup _{f\in {\mathcal {F}}}\int _{A}|f|\,d\mu =0$ , i.e. $\forall \ \varepsilon >0,\ \exists \ \delta _{\varepsilon }>0,\ \forall \ A\in {\mathcal {A}}:\mu (A)<\delta _{\varepsilon }\Rightarrow \sup _{f\in {\mathcal {F}}}\int _{A}|f|\,d\mu <\varepsilon$ . This definition is sometimes used as a definition of uniform integrability. However, it differs from the definition of uniform integrability given above.

When $\mu (X)<\infty$ , a set of functions ${\mathcal {F}}\subset L^{1}(X,{\mathcal {A}},\mu )$ is uniformly integrable if and only if it is bounded in $L^{1}(X,{\mathcal {A}},\mu )$ and has uniformly absolutely continuous integrals. If, in addition, $\mu$ is atomless, then the uniform integrability is equivalent to the uniform absolute continuity of integrals.

Finite measure case

Let $(X,{\mathcal {A}},\mu )$ be a measure space with $\mu (X)<\infty$ . Let $(f_{n})\subset L^{p}(X,{\mathcal {A}},\mu )$ and $f$ be an ${\mathcal {A}}$ -measurable function. Then, the following are equivalent :

$f\in L^{p}(X,{\mathcal {A}},\mu )$ and $(f_{n})$ converges to $f$ in $L^{p}(X,{\mathcal {A}},\mu )$ ;
The sequence of functions $(f_{n})$ converges in $\mu$ -measure to $f$ and $(|f_{n}|^{p})_{n\geq 1}$ is uniformly integrable ;

For a proof, see Bogachev's monograph "Measure Theory, Volume I".^[1]

Infinite measure case

Let $(X,{\mathcal {A}},\mu )$ be a measure space and $1\leq p<\infty$ . Let $(f_{n})_{n\geq 1}\subseteq L^{p}(X,{\mathcal {A}},\mu )$ and $f\in L^{p}(X,{\mathcal {A}},\mu )$ . Then, $(f_{n})$ converges to $f$ in $L^{p}(X,{\mathcal {A}},\mu )$ if and only if the following holds :

The sequence of functions $(f_{n})$ converges in $\mu$ -measure to $f$ ;
$(f_{n})$ has uniformly absolutely continuous integrals;
For every $\varepsilon >0$ , there exists $X_{\varepsilon }\in {\mathcal {A}}$ such that $\mu (X_{\varepsilon })<\infty$ and $\sup _{n\geq 1}\int _{X\setminus X_{\varepsilon }}|f_{n}|^{p}\,d\mu <\varepsilon .$

When $\mu (X)<\infty$ , the third condition becomes superfluous (one can simply take $X_{\varepsilon }=X$ ) and the first two conditions give the usual form of Lebesgue-Vitali's convergence theorem originally stated for measure spaces with finite measure. In this case, one can show that conditions 1 and 2 imply that the sequence $(|f_{n}|^{p})_{n\geq 1}$ is uniformly integrable.

Converse of the theorem

Let $(X,{\mathcal {A}},\mu )$ be measure space. Let $(f_{n})_{n\geq 1}\subseteq L^{1}(X,{\mathcal {A}},\mu )$ and assume that $\lim _{n\to \infty }\int _{A}f_{n}\,d\mu$ exists for every $A\in {\mathcal {A}}$ . Then, the sequence $(f_{n})$ is bounded in $L^{1}(X,{\mathcal {A}},\mu )$ and has uniformly absolutely continuous integrals. In addition, there exists $f\in L^{1}(X,{\mathcal {A}},\mu )$ such that $\lim _{n\to \infty }\int _{A}f_{n}\,d\mu =\int _{A}f\,d\mu$ for every $A\in {\mathcal {A}}$ .

When $\mu (X)<\infty$ , this implies that $(f_{n})$ is uniformly integrable.

For a proof, see Bogachev's monograph "Measure Theory, Volume I".^[1]

Citations

1 2 3 Bogachev, Vladimir I. (2007). Measure Theory Volume I. New York: Springer. pp. 267–271. ISBN 978-3-540-34513-8.

Related Research Articles

In mathematics, specifically in measure theory, a Borel measure on a topological space is a measure that is defined on all open sets. Some authors require additional restrictions on the measure, as described below.

In mathematics, the $L p$ spaces are function spaces defined using a natural generalization of the $p$ -norm for finite-dimensional vector spaces. They are sometimes called Lebesgue spaces, named after Henri Lebesgue, although according to the Bourbaki group they were first introduced by Frigyes Riesz.

In probability theory, there exist several different notions of convergence of sequences of random variables, including convergence in probability, convergence in distribution, and almost sure convergence. The different notions of convergence capture different properties about the sequence, with some notions of convergence being stronger than others. For example, convergence in distribution tells us about the limit distribution of a sequence of random variables. This is a weaker notion than convergence in probability, which tells us about the value a random variable will take, rather than just the distribution.

In the mathematical field of real analysis, the monotone convergence theorem is any of a number of related theorems proving the good convergence behaviour of monotonic sequences, i.e. sequences that are non-increasing, or non-decreasing. In its simplest form, it says that a non-decreasing bounded-above sequence of real numbers $converges to its smallest upper bound, its supremum. Likewise, a non-increasing bounded-below sequence converges to its largest lower bound, its infimum. In particular, infinite sums of non-negative numbers converge to the supremum of the partial sums if and only if the partial sums are bounded.$

In probability theory, the law of large numbers (LLN) is a mathematical law that states that the average of the results obtained from a large number of independent random samples converges to the true value, if it exists. More formally, the LLN states that given a sample of independent and identically distributed values, the sample mean converges to the true mean.

In mathematics, Fatou's lemma establishes an inequality relating the Lebesgue integral of the limit inferior of a sequence of functions to the limit inferior of integrals of these functions. The lemma is named after Pierre Fatou.

In mathematics, the Radon–Nikodym theorem is a result in measure theory that expresses the relationship between two measures defined on the same measurable space. A measure is a set function that assigns a consistent magnitude to the measurable subsets of a measurable space. Examples of a measure include area and volume, where the subsets are sets of points; or the probability of an event, which is a subset of possible outcomes within a wider probability space.

In measure theory, Lebesgue's dominated convergence theorem gives a mild sufficient condition under which limits and integrals of a sequence of functions can be interchanged. More technically it says that if a sequence of functions is bounded in absolute value by an integrable function and is almost everywhere point wise convergent to a function then the sequence converges in $to its point wise limit, and in particular the integral of the limit is the limit of the integrals. Its power and utility are two of the primary theoretical advantages of Lebesgue integration over Riemann integration.$

In mathematics, a Dirichlet series is any series of the form $where s is complex, and is a complex sequence. It is a special case of general Dirichlet series.$

In mathematics, mixing is an abstract concept originating from physics: the attempt to describe the irreversible thermodynamic process of mixing in the everyday world: e.g. mixing paint, mixing drinks, industrial mixing.

In measure theory, an area of mathematics, Egorov's theorem establishes a condition for the uniform convergence of a pointwise convergent sequence of measurable functions. It is also named Severini–Egoroff theorem or Severini–Egorov theorem, after Carlo Severini, an Italian mathematician, and Dmitri Egorov, a Russian mathematician and geometer, who published independent proofs respectively in 1910 and 1911.

In the theory of probability, the Glivenko–Cantelli theorem, named after Valery Ivanovich Glivenko and Francesco Paolo Cantelli, describes the asymptotic behaviour of the empirical distribution function as the number of independent and identically distributed observations grows. Specifically, the empirical distribution function converges uniformly to the true distribution function almost surely.

<span class="mw-page-title-main">Classical Wiener space</span>

In mathematics, classical Wiener space is the collection of all continuous functions on a given domain, taking values in a metric space. Classical Wiener space is useful in the study of stochastic processes whose sample paths are continuous functions. It is named after the American mathematician Norbert Wiener.

In mathematics, more specifically measure theory, there are various notions of the convergence of measures. For an intuitive general sense of what is meant by convergence of measures, consider a sequence of measures $μ n$ on a space, sharing a common collection of measurable sets. Such a sequence might represent an attempt to construct 'better and better' approximations to a desired measure $μ$ that is difficult to obtain directly. The meaning of 'better and better' is subject to all the usual caveats for taking limits; for any error tolerance $ε > 0$ we require there be $N$ sufficiently large for $n \geq N$ to ensure the 'difference' between $μ n$ and $μ$ is smaller than $ε$ . Various notions of convergence specify precisely what the word 'difference' should mean in that description; these notions are not equivalent to one another, and vary in strength.

Convergence in measure is either of two distinct mathematical concepts both of which generalize the concept of convergence in probability.

In mathematics, uniform integrability is an important concept in real analysis, functional analysis and measure theory, and plays a vital role in the theory of martingales.

In mathematics, the Cauchy–Hadamard theorem is a result in complex analysis named after the French mathematicians Augustin Louis Cauchy and Jacques Hadamard, describing the radius of convergence of a power series. It was published in 1821 by Cauchy, but remained relatively unknown until Hadamard rediscovered it. Hadamard's first publication of this result was in 1888; he also included it as part of his 1892 Ph.D. thesis.

In mathematics, the Christ–Kiselev maximal inequality is a maximal inequality for filtrations, named for mathematicians Michael Christ and Alexander Kiselev.

In the mathematical field of analysis, the Brezis–Lieb lemma is a basic result in measure theory. It is named for Haïm Brézis and Elliott Lieb, who discovered it in 1983. The lemma can be viewed as an improvement, in certain settings, of Fatou's lemma to an equality. As such, it has been useful for the study of many variational problems.

This is a glossary of concepts and results in real analysis and complex analysis in mathematics.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[:0-1] 1 2 3 Bogachev, Vladimir I. (2007). Measure Theory Volume I. New York: Springer. pp. 267–271. ISBN 978-3-540-34513-8.

[1]