Absolutely Continuous Measures: Difference between revisions
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:In particular, we proceed by contradiction and suppose there exists <math> \epsilon > 0</math> so that for any <math> \delta > 0 </math> and <math> \mu_1(T) < \delta</math>, we have <math> \mu_2(T) \geq \epsilon </math>. Now, define a sequence of sets <math> \{T_n\}_{n\in \mathbb{N}}\subseteq \mathcal{M}</math> such that <math> \mu_1(T_n) < \frac{\epsilon}{2^n}</math> and denote <math> T=\limsup{T_n}=\cap_{n=1}^{\infty} G_n \in \mathcal{M}</math> where <math> G_n = \cup_{k=n}^{\infty}T_k</math>. We have from countable subadditivity that <math> \mu_1(G_n) \leq \sum_{k=n}^{\infty} \mu_1(T_k)<\sum_{k=n}^{\infty} \frac{\epsilon}{2^k} = \frac{\epsilon}{2^{n+1}}\,\forall n\in\mathbb{N}</math>. We have from monotonicity that <math> \mu_2(G_n) \geq \epsilon \,\, \forall n\in \mathbb{N} </math>. The monotonicity of the measure <math> \mu_1 </math> implies that <math> \mu_1(\cap_{n=1}^{\infty} G_n)=\mu_1(\limsup{T_n}) = \mu_1(T) = 0 < \delta</math>. Applying continuity from above to <math> \mu_2</math>, we also have <math> \mu_2(T) \geq \epsilon </math>. However, this contradicts the definition of <math>\mu_2 \ll \mu_1</math>. | :In particular, we proceed by contradiction and suppose there exists <math> \epsilon > 0</math> so that for any <math> \delta > 0 </math> and <math> \mu_1(T) < \delta</math>, we have <math> \mu_2(T) \geq \epsilon </math>. Now, define a sequence of sets <math> \{T_n\}_{n\in \mathbb{N}}\subseteq \mathcal{M}</math> such that <math> \mu_1(T_n) < \frac{\epsilon}{2^n}</math> and denote <math> T=\limsup{T_n}=\cap_{n=1}^{\infty} G_n \in \mathcal{M}</math> where <math> G_n = \cup_{k=n}^{\infty}T_k</math>. We have from countable subadditivity that <math> \mu_1(G_n) \leq \sum_{k=n}^{\infty} \mu_1(T_k)<\sum_{k=n}^{\infty} \frac{\epsilon}{2^k} = \frac{\epsilon}{2^{n+1}}\,\forall n\in\mathbb{N}</math>. We have from monotonicity that <math> \mu_2(G_n) \geq \epsilon \,\, \forall n\in \mathbb{N} </math>. The monotonicity of the measure <math> \mu_1 </math> implies that <math> \mu_1(\cap_{n=1}^{\infty} G_n)=\mu_1(\limsup{T_n}) = \mu_1(T) = 0 < \delta</math>. Applying continuity from above to <math> \mu_2</math>, we also have <math> \mu_2(T) \geq \epsilon </math>. However, this contradicts the definition of <math>\mu_2 \ll \mu_1</math>. | ||
In fact, the converse to the above result also holds (see [3]). Namely, if we have <math> \forall \epsilon > 0</math> that there exists <math> \delta > 0</math> so that <math> \mu_1(T) < \delta \implies \mu_2(T) < \epsilon </math>, then <math> \mu_2 \ll \mu_1</math>. | In fact, the converse to the above result also holds (see [3]). Namely, if we have <math> \forall \epsilon > 0</math> that there exists <math> \delta > 0</math> so that <math> \mu_1(T) < \delta \implies \mu_2(T) < \epsilon </math>, then <math> \mu_2 \ll \mu_1</math>. Suppose that <math> \mu_1(T) = 0</math> for some <math> T\in \mathcal{M}</math>. Then, for any such <math> \epsilon > 0</math> as in the preceding claim, we have <math> \mu_1(T) = 0 < \delta \implies \mu_2(T) < \epsilon</math>. Since <math> \epsilon > 0</math> can be taken to be arbitrarily small, we have that <math> \mu_2(T) = 0</math>, as required for the measure <math> \mu_2</math> to be absolutely continuous with respect to <math> \mu_1</math>. | ||
==References== | ==References== | ||
[1]: Taylor, M. "Measure Theory and Integration". 50-51. | [1]: Taylor, M. "Measure Theory and Integration". 50-51. |
Revision as of 05:54, 19 December 2020
Definitions
Let be a measure space. The measure is said to be absolutely continuous with respect to the measure if we have that for such that (see [1]). In this case, we denote that is absolutely continuous with respect to by writing .
Examples
Recall that if is a measurable function, then the set function for is a measure on . Observe that if , then so that (see [3] for further details on this example and others).
Properties
It was previously established on a homework problem that for some nonnegative measurable defined on the measure space and some arbitrarily chosen , there exists such that whenever (see [2]). The method that was used to establish this result can also be used to show that, in a finite measure space, if , then for some arbitrarily chosen , there exists such that .
- In particular, we proceed by contradiction and suppose there exists so that for any and , we have . Now, define a sequence of sets such that and denote where . We have from countable subadditivity that . We have from monotonicity that . The monotonicity of the measure implies that . Applying continuity from above to , we also have . However, this contradicts the definition of .
In fact, the converse to the above result also holds (see [3]). Namely, if we have that there exists so that , then . Suppose that for some . Then, for any such as in the preceding claim, we have . Since can be taken to be arbitrarily small, we have that , as required for the measure to be absolutely continuous with respect to .
References
[1]: Taylor, M. "Measure Theory and Integration". 50-51.
[2]: Craig, K. "Math 201a: Homework 8". Fall 2020. Refer to question 2.
[3]: Rana, I. K. "Introduction to Measure and Integration". Second Edition. 311-313.