Difference between revisions of "Law of the iterated logarithm"

2020 Mathematics Subject Classification: Primary: 60F10 Secondary: 60F15 [MSN][ZBL]

A limit theorem in probability theory which is a refinement of the strong law of large numbers. Let $ X _ {1} , X _ {2} \dots $ be a sequence of random variables and let

$$ S _ {n} = X _ {1} + \dots + X _ {n} . $$

For simplicity one assumes that $ S _ {n} $ has zero median for each $ n $. While the theorem on the strong law of large numbers deals with conditions under which $ S _ {n} /a _ {n} \rightarrow 0 $ almost surely ( $ a.s. $) for $ n \rightarrow \infty $, where $ \{ a _ {n} \} $ is a sequence of numbers, the theorem on the law of the iterated logarithm deals with sequences of numbers $ \{ c _ {n} \} $ such that

$$ \tag{1 } \lim\limits _ {n \rightarrow \infty } \sup \frac{S _ {n} }{c _ {n} } = 1 \ ( a.s.) $$

or

$$ \tag{2 } \lim\limits _ {n \rightarrow \infty } \sup \frac{| S _ {n} | }{c _ {n} } = 1 \ ( a.s.). $$

Relation (1) is equivalent to

$$ {\mathsf P} \{ S _ {n} > ( 1 + \epsilon ) c _ {n} ( i.o.) \} = 0 $$

and

$$ {\mathsf P} \{ S _ {n} > ( 1 - \epsilon ) c _ {n} ( i.o.) \} = 1 $$

for any $ \epsilon > 0 $, where $ i.o. $ denotes infinitely often.

Relations of the form of (1) and (2) hold under more restrictive conditions than the estimates implied by the strong law of large numbers. If $ \{ X _ {n} \} $ is a sequence of independent random variables having identical distributions with mathematical expectations equal to zero, then

$$ \frac{S _ {n} }{n} \rightarrow 0 \ \textrm{ (a.s.) } \ \textrm{ for } n \rightarrow \infty $$

(Kolmogorov's theorem); if the additional condition $ 0 < {\mathsf E} X _ {1} ^ {2} < \infty $ is satisfied, then one has the stronger relation (2), in which

$$ c _ {n} = ( 2nb { \mathop{\rm ln} \mathop{\rm ln} } ( nb)) ^ {1/2} , $$

where $ b = {\mathsf E} X _ {1} ^ {2} $( the Hartman–Wintner theorem).

The first theorem of general type on the law of the iterated logarithm was the following result obtained by A.N. Kolmogorov [Ko]. Let $ \{ X _ {n} \} $ be a sequence of independent random variables with mathematical expectations equal to zero and with finite variances, and let

$$ B _ {n} = \sum _ { k= } 1 ^ { n } {\mathsf E} X _ {k} ^ {2} . $$

If $ B _ {n} \rightarrow \infty $ for $ n \rightarrow \infty $ and if there exists a sequence of positive constants $ \{ M _ {n} \} $ such that

$$ | X _ {n} | \leq M _ {n} \ \textrm{ and } \ \ M _ {n} = o \left ( \left ( \frac{B _ {n} }{ \mathop{\rm ln} \mathop{\rm ln} B _ {n} } \right ) ^ {1/2} \right ) , $$

then (1) and (2) are satisfied for

$$ c _ {n} = ( 2B _ {n} \mathop{\rm ln} \mathop{\rm ln} B _ {n} ) ^ {1/2} . $$

In the particular case where $ \{ X _ {n} \} $ is a sequence of independent random variables having identical distributions with two possible values, this assertion was derived by A.Ya. Khinchin [Kh]. J. Marcinkiewicz and A. Zygmund [MZ] showed that under the conditions of Kolmogorov's theorem one cannot replace $ o $ by $ O $. W. Feller [F] examined a generalization of Kolmogorov's law of the iterated logarithm for sequences of independent bounded non-identically distributed random variables. See [S] for other generalizations of the law; there is also the following result (see [S2]), which is related to the Hartman–Wintner theorem: If $ \{ X _ {n} \} $ is a sequence of independent random variables having identical distributions with infinite variances, then

$$ \lim\limits _ {n \rightarrow \infty } \sup \frac{| S _ {n} | }{( n \mathop{\rm ln} n \mathop{\rm ln} n) ^ {1/2} } = \infty \ ( a.s.). $$

The results obtained on the law of the iterated logarithm for sequences of independent random variables have served as a starting point for numerous researches on the applicability of this law to sequences of dependent random variables and vectors and to random processes.

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