The Ultimate Absolute continuity - American History Information Guide and Reference

Absolute continuity of real functions

In mathematics, a real-valued function f of a real variable is absolutely continuous if for every positive number ε, no matter how small, there is a positive number δ small enough so that whenever a sequence of pairwise disjoint intervals [x_k, y_k], k = 1, ..., n satisfies

$\sum_{k=1}^n (y_k-x_k)<\delta$

then

$\sum_{k=1}^n\left|f(y_k)-f(x_k)\right|<\varepsilon.$

Every absolutely continuous function is uniformly continuous and, therefore, continuous. Every Lipschitz-continuous function is absolutely continuous.

The Cantor function is continuous everywhere but not absolutely continuous.

Absolute continuity of measures

If μ and ν are measures on the same measure space (or, more precisely, on the same sigma-algebra) then μ is absolutely continuous with respect to ν if μ(A) = 0 for every set A for which ν(A) = 0. One writes "μ << ν".

The Radon-Nikodym theorem states that if μ is absolutely continuous with respect to ν, and ν is σ-finite, then μ has a density, or "Radon-Nikodym derivative", with respect to ν, i.e., a measurable function f taking values in [0,∞], denoted by f = dμ/dν, such that for any measurable set A we have

$\mu(A)=\int_A f\,d\nu.$

The connection between absolute continuity of real functions and absolute continuity of measures

A measure μ on Borel subsets of the real line is absolutely continuous with respect to Lebesgue measure if and only if the point function

$F(x)=\mu((-\infty,x])$

is an absolutely continuous real function.

Your American History Reference Guide! - Absolute continuity

Absolute continuity

Absolute continuity of real functions

Absolute continuity of measures

The connection between absolute continuity of real functions and absolute continuity of measures

Your American History Reference Guide!
- Absolute continuity