Slowly varying function

In real analysis, a branch of mathematics, a slowly varying function is a function of a real variable whose behaviour at infinity is in some sense similar to the behaviour of a function converging at infinity. Similarly, a regularly varying function is a function of a real variable whose behaviour at infinity is similar to the behaviour of a power law function (like a polynomial) near infinity. These classes of functions were both introduced by Jovan Karamata,^[1]^[2] and have found several important applications, for example in probability theory.

Basic definitions

Definition 1. A function $L : (0,+\infty) \to (0,+\infty)$ is called slowly varying (at infinity) if for all $a > 0$ ,

\lim_{x \to \infty} \frac{L(ax)}{L(x)}=1.

Definition 2. A function $L : (0,+\infty) \to (0,+\infty)$ for which the limit

g(a) = \lim_{x \to \infty} \frac{L(ax)}{L(x)}

is finite but nonzero for every $a > 0$ , is called a regularly varying function.

These definitions are due to Jovan Karamata.^[1]^[2]

Basic properties

Regularly varying functions have some important properties:^[1] a partial list of them is reported below. More extensive analyses of the properties characterizing regular variation are presented in the monograph by Bingham, Goldie & Teugels (1989).

Uniformity of the limiting behaviour

Theorem 1. The limit in definitions 1 and 2 is uniform if $a$ is restricted to a finite interval.

Karamata's characterization theorem

Theorem 2. Every regularly varying function $f$ is of the form

f(x)=x^\beta L(x)

where

$β \geq 0$ is a non negative real number
$L$ is a slowly varying function.

Note. This implies that the function $g (a)$ in definition 2 has necessarily to be of the following form

g(a)=a^\rho

where the non negative real number $ρ$ is called the index of regular variation.

Karamata representation theorem

Theorem 3. A function $L$ is slowly varying if and only if there exists $B > 0$ such that for all $x \geq B$ the function can be written in the form

L(x) = \exp \left( \eta(x) + \int_B^x \frac{\varepsilon(t)}{t} \,dt \right)

where

$η (x)$ is a bounded measurable function of a real variable converging to a finite number as $x$ goes to infinity
$ε (x)$ is a bounded measurable function of a real variable converging to zero as $x$ goes to infinity.

Examples

If $L$ has a limit

\lim_{x \to \infty} L(x) = b \in (0,\infty),

then

L

is a slowly varying function.

For any $β \in R$ , the function $L (x) = log β x$ is slowly varying.
The function $L (x) = x$ is not slowly varying, neither is $L (x) = x β$ for any real $β \neq 0$ . However, these functions are regularly varying.

Notes

↑ ^1.0 ^1.1 ^1.2 See (Galambos & Seneta 1973)
↑ ^2.0 ^2.1 See (Bingham, Goldie & Teugels 1989).

References

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[GaSe-1] 1.0 ^1.1 ^1.2 See (Galambos & Seneta 1973)

[BiGoTe-2] 2.0 ^2.1 See (Bingham, Goldie & Teugels 1989).

[1]

[2]

Slowly varying function

Contents

Basic definitions

Basic properties

Uniformity of the limiting behaviour

Karamata's characterization theorem

Karamata representation theorem

Examples

See also

Notes

References

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