Vitali convergence theorem

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 strong condition that depends on uniform integrability. It is useful when a dominating function cannot be found for the sequence of functions in question; when such a dominating function can be found, Lebesgue's theorem follows as a special case of Vitali's.

Statement of the theorem

Let $(X,\mathcal{F},\mu)$ be a positive measure space. If

$\mu(X)<\infty$
$\{f_{n}\}$ is uniformly integrable
$f_n(x)\to f(x)$ a.e. as $n\to \infty$ and
$|f(x)|<\infty$ a.e.

then the following hold:

$f\in \mathcal{L}^1(\mu)$
$\lim_{n\to \infty} \int_{X}|f_n-f|d\mu=0$ .^[1]

Outline of Proof

For proving statement 1, we use Fatou's lemma:

\int_X|f|d\mu\le \liminf_{n\to\infty} \int_X|f_n|d\mu

Using uniform integrability there exists $\delta >0$ such that we have $\int_E |f_n|d\mu<1$ for every set $E$ with $\mu(E)<\delta$
By Egorov's theorem, ${f_n}$ converges uniformly on the set $E^C$ . $\int_{E^C}|f_n-f_p|d\mu<1$ for a large $p$ and $\forall n>p$ . Using triangle inequality, $\int_{E^C}|f_n|d\mu\le \int_{E^C}|f_p|d\mu+1=M$
Plugging the above bounds on the RHS of Fatou's lemma gives us statement 1.

For statement 2, use

\int_{X}|f-f_n|d\mu\le \int_{E}|f|d\mu+\int_{E}|f_n|d\mu+\int_{E^C}|f-f_n|d\mu

, where

E\in \mathcal{F}

and

\mu(E)<\delta

.

The terms in the RHS are bounded respectively using Statement 1, uniform integrability of $f_{n}$ and Egorov's theorem for all $n>N$ .

Converse of the theorem

Let $(X,\mathcal{F},\mu)$ be a positive measure space. If

$\mu(X)<\infty$ ,
$f_n\in \mathcal{L}^1(\mu)$ and
$\lim_{n\to\infty}\int_E f_nd\mu$ exists for every $E\in\mathcal{F}$

then $\{f_{n}\}$ is uniformly integrable.^[1]

Citations

1 2 Rudin, Walter (1986). Real and Complex Analysis. p. 133. ISBN 978-0-07-054234-1.

References

Folland, Gerald B. (1999). Real analysis. Pure and Applied Mathematics (New York) (Second ed.). New York: John Wiley & Sons Inc. pp. xvi+386. ISBN 0-471-31716-0. MR 1681462
Rosenthal, Jeffrey S. (2006). A first look at rigorous probability theory (Second ed.). Hackensack, NJ: World Scientific Publishing Co. Pte. Ltd. pp. xvi+219. ISBN 978-981-270-371-2. MR 2279622

External links

Vitali convergence theorem at PlanetMath.org.

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