Uniform integrability

Uniform integrability is an extension to the notion of a family of functions being dominated in ${\displaystyle L_{1}}$  which is central in dominated convergence. Several textbooks on real analysis and measure theory use the following definition:^[1][2]

Definition A: Let ${\displaystyle (X,{\mathfrak {M}},\mu )}$  be a positive measure space. A set ${\displaystyle \Phi \subset L^{1}(\mu )}$  is called uniformly integrable if ${\displaystyle \sup _{f\in \Phi }\|f\|_{L_{1}(\mu )}<\infty }$ , and to each ${\displaystyle \varepsilon >0}$  there corresponds a ${\displaystyle \delta >0}$  such that

${\displaystyle \int _{E}|f|\,d\mu <\varepsilon }$ 

whenever ${\displaystyle f\in \Phi }$  and ${\displaystyle \mu (E)<\delta .}$ 

Definition A is rather restrictive for infinite measure spaces. A more general definition^[3] of uniform integrability that works well in general measures spaces was introduced by G. A. Hunt.

Definition H: Let ${\displaystyle (X,{\mathfrak {M}},\mu )}$  be a positive measure space. A set ${\displaystyle \Phi \subset L^{1}(\mu )}$  is called uniformly integrable if and only if

${\displaystyle \inf _{g\in L_{+}^{1}(\mu )}\sup _{f\in \Phi }\int _{\{|f|>g\}}|f|\,d\mu =0}$ 

where ${\displaystyle L_{+}^{1}(\mu )=\{g\in L^{1}(\mu ):g\geq 0\}}$ .

Since Hunt's definition is equivalent to Definition A when the underlying measure space is finite (see Theorem 2 below), Definition H is widely adopted in Mathematics.

The following result^[4] provides another equivalent notion to Hunt's. This equivalency is sometimes given as definition for uniform integrability.

Theorem 1: If ${\displaystyle (X,{\mathfrak {M}},\mu )}$  is a (positive) finite measure space, then a set ${\displaystyle \Phi \subset L^{1}(\mu )}$  is uniformly integrable if and only if

${\displaystyle \inf _{g\in L_{+}^{1}(\mu )}\sup _{f\in \Phi }\int (|f|-g)^{+}\,d\mu =0}$ 

If in addition ${\displaystyle \mu (X)<\infty }$ , then uniform integrability is equivalent to either of the following conditions

1. ${\displaystyle \inf _{a>0}\sup _{f\in \Phi }\int (|f|-a)_{+}\,d\mu =0}$ .

2. ${\displaystyle \inf _{a>0}\sup _{f\in \Phi }\int _{\{|f|>a\}}|f|\,d\mu =0}$ 

When the underlying space ${\displaystyle (X,{\mathfrak {M}},\mu )}$  is ${\displaystyle \sigma }$ -finite, Hunt's definition is equivalent to the following:

Theorem 2: Let ${\displaystyle (X,{\mathfrak {M}},\mu )}$  be a ${\displaystyle \sigma }$ -finite measure space, and ${\displaystyle h\in L^{1}(\mu )}$  be such that ${\displaystyle h>0}$  almost everywhere. A set ${\displaystyle \Phi \subset L^{1}(\mu )}$  is uniformly integrable if and only if ${\displaystyle \sup _{f\in \Phi }\|f\|_{L_{1}(\mu )}<\infty }$ , and for any ${\displaystyle \varepsilon >0}$ , there exits ${\displaystyle \delta >0}$  such that

${\displaystyle \sup _{f\in \Phi }\int _{A}|f|\,d\mu <\varepsilon }$ 

whenever ${\displaystyle \int _{A}h\,d\mu <\delta }$ .

A consequence of Theorems 1 and 2 is that equivalence of Definitions A and H for finite measures follows. Indeed, the statement in Definition A is obtained by taking ${\displaystyle h\equiv 1}$  in Theorem 2.

In the theory of probability, Definition A or the statement of Theorem 1 are often presented as definitions of uniform integrability using the notation expectation of random variables.,^[5][6][7] that is,

1. A class ${\displaystyle {\mathcal {C}}}$  of random variables is called uniformly integrable if:

• There exists a finite ${\displaystyle M}$  such that, for every ${\displaystyle X}$  in ${\displaystyle {\mathcal {C}}}$ , ${\displaystyle \operatorname {E} (|X|)\leq M}$  and
• For every ${\displaystyle \varepsilon >0}$  there exists ${\displaystyle \delta >0}$  such that, for every measurable ${\displaystyle A}$  such that ${\displaystyle P(A)\leq \delta }$  and every ${\displaystyle X}$  in ${\displaystyle {\mathcal {C}}}$ , ${\displaystyle \operatorname {E} (|X|I_{A})\leq \varepsilon }$ .

or alternatively

2. A class ${\displaystyle {\mathcal {C}}}$  of random variables is called uniformly integrable (UI) if for every ${\displaystyle \varepsilon >0}$  there exists ${\displaystyle K\in [0,\infty )}$  such that ${\displaystyle \operatorname {E} (|X|I_{|X|\geq K})\leq \varepsilon \ {\text{ for all }}X\in {\mathcal {C}}}$ , where ${\displaystyle I_{|X|\geq K}}$  is the indicator function ${\displaystyle I_{|X|\geq K}={\begin{cases}1&{\text{if }}|X|\geq K,\\0&{\text{if }}|X|<K.\end{cases}}}$ .

Another concept associated with uniform integrability is that of tightness. In this article tightness is taken in a more general setting.

Definition: Suppose measurable space ${\displaystyle (X,{\mathfrak {M}},\mu )}$  is a measure space. Let ${\displaystyle {\mathcal {K}}\subset {\mathfrak {M}}}$  be a collection of sets of finite measure. A family ${\displaystyle \Phi \subset L_{1}(\mu )}$  is tight with respect to ${\displaystyle {\mathcal {K}}}$  if

${\displaystyle \inf _{K\in {\mathcal {K}}}\sup _{f\in \Phi }\int _{X\setminus K}|f|\,\mu =0}$ 

A tight family with respect to ${\displaystyle \Phi ={\mathfrak {M}}\cap L_{1}(\,u)}$  is just said to be tight.

When the measure space ${\displaystyle (X,{\mathfrak {M}},\mu )}$  is a metric space equipped with the Borel ${\displaystyle \sigma }$  algebra, ${\displaystyle \mu }$  is a regular measure, and ${\displaystyle {\mathcal {K}}}$  is the collection of all compact subsets of ${\displaystyle X}$ , the notion of ${\displaystyle {\mathcal {K}}}$ -tightness discussed above coincides with the well known concept of tightness used in the analysis of regular measures in metric spaces

For ${\displaystyle \sigma }$ -finite measure spaces, it can be shown that if a family ${\displaystyle \Phi \subset L_{1}(\mu )}$  is uniformly integrable, then ${\displaystyle \Phi }$  is tight. This is capture by the following result which is often used as definition of uniform integrabiliy in the Analysis literature:

Theorem 3: Suppose ${\displaystyle (X,{\mathfrak {M}},\mu )}$  is a ${\displaystyle \sigma }$  finite measure space. A family ${\displaystyle \Phi \subset L_{1}(\mu )}$  is uniformly integrable if and only if

1. ${\displaystyle \sup _{f\in \Phi }\|f\|_{1}<\infty }$ .
2. ${\displaystyle \inf _{a>0}\sup _{f\in \Phi }\int _{\{|f|>a\}}|f|\,d\mu =0}$ 
3. ${\displaystyle \Phi }$  is tight.

When ${\displaystyle \mu (X)<\infty }$ , condition 3 is redundant (see Theorem 1 above).

There is another notion of uniformity, slightly different than uniform integrability, which also has many applications in probability and measure theory, and which does not require random variables to have a finite integral^[8]

Definition: Suppose ${\displaystyle (\Omega ,{\mathcal {F}},P)}$  is a probability space. A class ${\displaystyle {\mathcal {C}}}$  of random variables is uniformly absolutely continuous with respect to ${\displaystyle P}$  if for any ${\displaystyle \varepsilon >0}$ , there is ${\displaystyle \delta >0}$  such that ${\displaystyle E[|X|I_{A}]<\varepsilon }$  whenever ${\displaystyle P(A)<\delta }$ .

It is equivalent to uniform integrability if the measure is finite and has no atoms.

The term "uniform absolute continuity" is not standard,^{[citation needed]} but is used by some authors.^[9][10]

The following results apply to the probabilistic definition.^[11]

• Definition 1 could be rewritten by taking the limits as $${\displaystyle \lim _{K\to \infty }\sup _{X\in {\mathcal {C}}}\operatorname {E} (|X|\,I_{|X|\geq K})=0.}$$ 
• A non-UI sequence. Let ${\displaystyle \Omega =[0,1]\subset \mathbb {R} }$ , and define $${\displaystyle X_{n}(\omega )={\begin{cases}n,&\omega \in (0,1/n),\\0,&{\text{otherwise.}}\end{cases}}}$$  Clearly ${\displaystyle X_{n}\in L^{1}}$ , and indeed ${\displaystyle \operatorname {E} (|X_{n}|)=1\ ,}$  for all n. However, $${\displaystyle \operatorname {E} (|X_{n}|I_{\{|X_{n}|\geq K\}})=1\ {\text{ for all }}n\geq K,}$$  and comparing with definition 1, it is seen that the sequence is not uniformly integrable.

• By using Definition 2 in the above example, it can be seen that the first clause is satisfied as ${\displaystyle L^{1}}$  norm of all ${\displaystyle X_{n}}$ s are 1 i.e., bounded. But the second clause does not hold as given any ${\displaystyle \delta }$  positive, there is an interval ${\displaystyle (0,1/n)}$  with measure less than ${\displaystyle \delta }$  and ${\displaystyle E[|X_{m}|:(0,1/n)]=1}$  for all ${\displaystyle m\geq n}$ .
• If ${\displaystyle X}$  is a UI random variable, by splitting $${\displaystyle \operatorname {E} (|X|)=\operatorname {E} (|X|I_{\{|X|\geq K\}})+\operatorname {E} (|X|I_{\{|X|<K\}})}$$  and bounding each of the two, it can be seen that a uniformly integrable random variable is always bounded in ${\displaystyle L^{1}}$ .
• If any sequence of random variables ${\displaystyle X_{n}}$  is dominated by an integrable, non-negative ${\displaystyle Y}$ : that is, for all ω and n, $${\displaystyle |X_{n}(\omega )|\leq Y(\omega ),\ Y(\omega )\geq 0,\ \operatorname {E} (Y)<\infty ,}$$  then the class ${\displaystyle {\mathcal {C}}}$  of random variables ${\displaystyle \{X_{n}\}}$  is uniformly integrable.
• A class of random variables bounded in ${\displaystyle L^{p}}$  (${\displaystyle p>1}$ ) is uniformly integrable.

In the following we use the probabilistic framework, but regardless of the finiteness of the measure, by adding the boundedness condition on the chosen subset of ${\displaystyle L^{1}(\mu )}$ .

• Dunford–Pettis theorem^[12][13]
  A class^{[clarification needed]} of random variables ${\displaystyle X_{n}\subset L^{1}(\mu )}$  is uniformly integrable if and only if it is relatively compact for the weak topology ${\displaystyle \sigma (L^{1},L^{\infty })}$ .^{[clarification needed][citation needed]}
• de la Vallée-Poussin theorem^[14][15]
  The family ${\displaystyle \{X_{\alpha }\}_{\alpha \in \mathrm {A} }\subset L^{1}(\mu )}$  is uniformly integrable if and only if there exists a non-negative increasing convex function ${\displaystyle G(t)}$  such that $${\displaystyle \lim _{t\to \infty }{\frac {G(t)}{t}}=\infty {\text{ and }}\sup _{\alpha }\operatorname {E} (G(|X_{\alpha }|))<\infty .}$$ 

A family of random variables ${\displaystyle \{X_{i}\}_{i\in I}}$  is uniformly integrable if and only if^[16] there exists a random variable ${\displaystyle X}$  such that ${\displaystyle EX<\infty }$  and ${\displaystyle |X_{i}|\leq _{\mathrm {icx} }X}$  for all ${\displaystyle i\in I}$ , where ${\displaystyle \leq _{\mathrm {icx} }}$  denotes the increasing convex stochastic order defined by ${\displaystyle A\leq _{\mathrm {icx} }B}$  if ${\displaystyle E\phi (A)\leq E\phi (B)}$  for all nondecreasing convex real functions ${\displaystyle \phi }$ .

A sequence ${\displaystyle \{X_{n}\}}$  converges to ${\displaystyle X}$  in the ${\displaystyle L_{1}}$  norm if and only if it converges in measure to ${\displaystyle X}$  and it is uniformly integrable. In probability terms, a sequence of random variables converging in probability also converge in the mean if and only if they are uniformly integrable.^[17] This is a generalization of Lebesgue's dominated convergence theorem, see Vitali convergence theorem.

• Shiryaev, A.N. (1995). Probability (2 ed.). New York: Springer-Verlag. pp. 187–188. ISBN 978-0-387-94549-1.
• Diestel, J. and Uhl, J. (1977). Vector measures, Mathematical Surveys 15, American Mathematical Society, Providence, RI ISBN 978-0-8218-1515-1