Simple Function: Difference between revisions
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==Properties of Simple Functions== | ==Properties of Simple Functions== | ||
Given simple functions <math>fig \in L^+</math>, the following are true: | |||
* if <math>c \geq 0, \int c f = c \int f</math>; | |||
* <math>\int (f + g) = \int f + \int g</math>; | |||
* if <math>f \leq g</math>, then <math>\int f \leq \int g</math>; | |||
* the function <math>A \mapsto \int_A f</math> is a measure on <math>\mathcal{M}</math>. | |||
==References== | ==References== |
Revision as of 01:36, 10 December 2020
The simplest functions you will ever integrate, hence the name.
Definition
Let be a measure space. A measurable function is a simple function[1] if is a finite subset of . The standard representation for a simple function is given by
,
where is the indicator function on the disjoint sets that partition , where .
Integration of Simple Functions
These functions earn their name from the simplicity in which their integrals are defined[2]. Let be the space of all measurable functions from to Then
where by convention, we let . Note that is equivalent to and that some arguments may be omitted when there is no confusion.
Furthermore, for any , we define
Properties of Simple Functions
Given simple functions , the following are true:
- if ;
- ;
- if , then ;
- the function is a measure on .