Difference between revisions of "Integral of a positive function (measure theory)"

From Maths
Jump to: navigation, search
(Created page with "==Definition== {{:Integral of a positive function (measure theory)/Definition}} There are alternate notations, that make the ''variable of integration'' more clear, they are:...")
(No difference)

Revision as of 12:59, 12 March 2016

Definition

Let [ilmath](X,\mathcal{A},\mu)[/ilmath] be a measure space, the [ilmath]\mu[/ilmath]-integral of a positive numerical function, [ilmath]f\in\mathcal{M}^+_{\bar{\mathbb{R} } }(\mathcal{A}) [/ilmath][Note 1][Note 2] is[1]:

  • [math]\int f\mathrm{d}\mu:=\text{Sup}\left\{I_\mu(g)\ \Big\vert\ g\le f, g\in\mathcal{E}^+(\mathcal{A})\right\}[/math][Note 3]

Recall that:

There are alternate notations, that make the variable of integration more clear, they are:

  • [ilmath]\int f(x)\mu(\mathrm{d}x)[/ilmath][1]
  • [ilmath]\int f(x)\mathrm{d}\mu(x)[/ilmath][1]

Immediate results

  • [math]\forall f\in\mathcal{E}^+(\mathcal{A})\left[\int f\mathrm{d}\mu=I_\mu(f)\right][/math] - Integrating a simple function works

Note that without this lemma we cannot be sure the integral of simple functions is well defined! Which would be really really bad if it weren't true.

(Unknown grade)
This page requires one or more proofs to be filled in, it is on a to-do list for being expanded with them.
Please note that this does not mean the content is unreliable. Unless there are any caveats mentioned below the statement comes from a reliable source. As always, Warnings and limitations will be clearly shown and possibly highlighted if very important (see template:Caution et al).
The message provided is:
Page 70 in[1]

Notes

  1. So [ilmath]f:X\rightarrow\bar{\mathbb{R} }^+[/ilmath]
  2. Notice that [ilmath]f[/ilmath] is [ilmath]\mathcal{A}/\bar{\mathcal{B} } [/ilmath]-measurable by definition, as [ilmath]\mathcal{M}_\mathcal{Z}(\mathcal{A})[/ilmath] denotes all the measurable functions that are [ilmath]\mathcal{A}/\mathcal{Z} [/ilmath]-measurable, we just use the [ilmath]+[/ilmath] as a slight abuse of notation to denote all the positive ones (with respect to the standard order on [ilmath]\bar{\mathbb{R} } [/ilmath] - the extended reals)
  3. The [ilmath]g\le f[/ilmath] is an abuse of notation for saying that [ilmath]g[/ilmath] is everywhere less than [ilmath]f[/ilmath], we could have written:
    • [math]\int f\mathrm{d}\mu=\text{Sup}\left\{I_\mu(g)\ \Big\vert\ g\le f, g\in\mathcal{E}^+\right\}=\text{Sup}\left\{I_\mu(g)\ \Big\vert\ g\in\left\{h\in\mathcal{E}^+(\mathcal{A})\ \big\vert\ \forall x\in X\left(h(x)\le f(x)\right)\right\}\right\}[/math] instead.
    Inline with: Notation for dealing with (extended) real-valued measurable maps

References

  1. 1.0 1.1 1.2 1.3 Measures, Integrals and Martingales - René L. Schilling

v  d  e
 
Measure Theory
Overview of the basic and important objects studied in measure theory
Set-structures
Measures
Pre-measure [ilmath]\leadsto[/ilmath] outer-measure [ilmath]\leadsto[/ilmath] measure (see Extending pre-measures to measures (via: Extending pre-measures to outer-measures [ilmath]\rightarrow[/ilmath] "Restricting outer-measures to measures" maybe?). Alternatively: inner-measure can be used.
measure space
Functions
Spaces
Integrals
Integrating a simple function [ilmath]\leadsto[/ilmath] Integral of a positive function [ilmath]\leadsto[/ilmath] Integrating all measurable functions



Retrieved from "https://www.maths.kisogo.com/index.php?title=Integral_of_a_positive_function_(measure_theory)&oldid=1917"