Egerov's Theorem: Difference between revisions

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==Proof==
==Proof==
WLOG assume <math> f_n \rightarrow f </math> for all <math> x \in E </math> since the set of points at which <math>f_n \rightarrow f</math> is a null set. Fix <math>\epsilon>0 </math> and for <math> n, k \in \N </math> we define
WLOG assume <math> f_n \rightarrow f </math> for all <math> x \in E </math> since the set of points at which <math>f_n \nrightarrow f</math> is a null set. Fix <math>\epsilon>0 </math> and for <math> n, k \in \N </math> we define
<math> E_k^n=\{x \in E: |f_j(x)-f(x)|<\frac{1}{n} \text{  for all  } j>k\} </math>. Since <math>f_n,f </math> are measurable so is their difference. Then since the absolute value of a measurable function is measurable each <math>E_k^n </math> is measurable.  
<math> E_k^n=\{x \in E: |f_j(x)-f(x)|<\frac{1}{n} \text{  for all  } j>k\} </math>. Since <math>f_n,f </math> are measurable so is their difference. Then since the absolute value of a measurable function is measurable each <math>E_k^n </math> is measurable.  


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Finally, since <math>\tilde{A}_\epsilon </math> is measurable, using HW5 problem 6 there exists a closed set <math>A_\epsilon\subset \tilde{A}_\epsilon </math> such that <math>\mu(\tilde{A}_\epsilon\setminus A_\epsilon)<\frac{\epsilon}{2} </math>. Therefore <math> \mu(E\setminus A_\epsilon)<\epsilon </math> and <math> f_n \rightarrow f </math> on <math> A_\epsilon </math>
Finally, since <math>\tilde{A}_\epsilon </math> is measurable, using HW5 problem 6 there exists a closed set <math>A_\epsilon\subset \tilde{A}_\epsilon </math> such that <math>\mu(\tilde{A}_\epsilon\setminus A_\epsilon)<\frac{\epsilon}{2} </math>. Therefore <math> \mu(E\setminus A_\epsilon)<\epsilon </math> and <math> f_n \rightarrow f </math> on <math> A_\epsilon </math>
==Corollary==
<strong> Bounded Convergence Theorem </strong>: Let <math> f_n </math> be a seqeunce of measurable functions bounded by <math> M </math>, supported on a set <math> E </math> and <math> f_n \to f </math> a.e. Then
<math> \lim_{n \to +\infty}\int f_n=\int\lim_{n \to +\infty} f_n=\int f </math> <ref name="SS2"> Stein & Shakarchi, ''Real Analysis: Measure Theory, Integration, and Hilbert Spaces'', Chapter 2 § 1 </ref>
==Proof==
By assumptions on <math> f_n</math>, <math>f </math> is measurable, bounded, supported on <math>E </math> for a.e. x. Fix <math>\epsilon>0 </math>, then by Egerov we may find a measurable subset <math>A_\epsilon </math> of <math> E</math> such that <math> \mu(E\setminus A_\epsilon)<\epsilon </math> and <math>f_n\to f </math> uniformly on <math>A_\epsilon </math>. Therefore, for sufficiently large <math>n </math> we have that <math>|f_n(x)-f(x)|<\epsilon </math> for all <math>x\in A_\epsilon </math>. Putting this together yields
<math>\int |f_n-f|=\int_E |f_n-f|=\int_{A_\epsilon} |f_n-f|+\int_{E\setminus A_\epsilon}\leq \epsilon \mu(E)+2M \mu(E\setminus A_\epsilon)=\epsilon(\mu(E)+2M) </math>
Since <math> \epsilon </math> was arbitrary and <math> \mu(E)+2M </math> is finite by assumption we are done.


==References==
==References==

Latest revision as of 21:02, 7 December 2020

Statement

Suppose is a locally finite Borel measure and is a sequence of measurable functions defined on a measurable set with and a.e. on E.

Then: Given we may find a closed subset such that and uniformly on [1]

Proof

WLOG assume for all since the set of points at which is a null set. Fix and for we define . Since are measurable so is their difference. Then since the absolute value of a measurable function is measurable each is measurable.

Now for fixed we have that and . Therefore using continuity from below we may find a such that . Now choose so that and define . By countable subadditivity we have that .

Fix any . We choose such that . Since if then . And by definition if then whenever . Hence uniformly on .

Finally, since is measurable, using HW5 problem 6 there exists a closed set such that . Therefore and on


Corollary

Bounded Convergence Theorem : Let be a seqeunce of measurable functions bounded by , supported on a set and a.e. Then

[2]

Proof

By assumptions on , is measurable, bounded, supported on for a.e. x. Fix , then by Egerov we may find a measurable subset of such that and uniformly on . Therefore, for sufficiently large we have that for all . Putting this together yields

Since was arbitrary and is finite by assumption we are done.

References

  1. Stein & Shakarchi, Real Analysis: Measure Theory, Integration, and Hilbert Spaces, Chapter 1 §4.3
  2. Stein & Shakarchi, Real Analysis: Measure Theory, Integration, and Hilbert Spaces, Chapter 2 § 1