Regular measure explained

In mathematics, a regular measure on a topological space is a measure for which every measurable set can be approximated from above by open measurable sets and from below by compact measurable sets.

Definition

Let (XT) be a topological space and let Σ be a σ-algebra on X. Let μ be a measure on (X, Σ). A measurable subset A of X is said to be inner regular if

\mu(A)=\sup\{\mu(F)\midF\subseteqA,Fcompactandmeasurable\}

and said to be outer regular if

\mu(A)=inf\{\mu(G)\midG\supseteqA,Gopenandmeasurable\}

Examples

Regular measures

Inner regular measures that are not outer regular

\mu

where

\mu(\emptyset)=0

,

\mu\left(\{1\}\right)=0

, and

\mu(A)=infty

for any other set

A

.

\mu

on a locally compact Hausdorff space that is inner regular, σ-finite, and locally finite but not outer regular is given by as follows. The topological space

X

has as underlying set the subset of the real plane given by the y-axis

\{0\} x R

together with the points (1/n,m/n2) with m,n positive integers. The topology is given as follows. The single points (1/n,m/n2) are all open sets. A base of neighborhoods of the point (0,y) is given by wedges consisting of all points in X of the form (u,v) with |v − y| ≤ |u| ≤ 1/n for a positive integer n. This space X is locally compact. The measure μ is given by letting the y-axis have measure 0 and letting the point (1/n,m/n2) have measure 1/n3. This measure is inner regular and locally finite, but is not outer regular as any open set containing the y-axis has measure infinity.

Outer regular measures that are not inner regular

Measures that are neither inner nor outer regular

See also

References