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So <math>m(A)<\delta \Rightarrow \int_A|f_n| <\epsilon \ \forall \ n</math>.
 
So <math>m(A)<\delta \Rightarrow \int_A|f_n| <\epsilon \ \forall \ n</math>.
 +
 +
[[Back|https://balthier.ecn.purdue.edu/index.php/MA544_Qual_Prep_%2708]]
  
 
  --[[User:Wardbc|Wardbc]] 20:17, 1 July 2008 (EDT)Ben Ward
 
  --[[User:Wardbc|Wardbc]] 20:17, 1 July 2008 (EDT)Ben Ward

Revision as of 20:19, 1 July 2008

8.

Fix $ \epsilon > 0 $.

Then $ \exists \ N $ such that $ n>N \Rightarrow \int_X|f_n-f|^p <\epsilon/3 $.

Define $ f_0=f $.

Then for $ i=0,1,...,N \ \exists \ \delta_i>0 $ such that $ m(A) <\delta_i \Rightarrow \int_A|f_i|^p<\epsilon/3 $, since $ f_i \in L^p $.


Define $ \delta=min\{\delta_0, \delta_1,...,\delta_N, \epsilon/3\} $.

Fix A with $ m(A)<\delta $.

Note: $ \int_A|f_n| = \int_{\{x\in A:|f_n|\leq1\}}|f_n|+\int_{\{x\in A:|f_n|>1\}}|f_n| \leq m(A) + \int_A|f_n|^p \leq \epsilon/3 + \int_A|f_n|^p \ \ \forall \ n=0,1,... $.

Then if n = 1,...,N

$ \int_A|f_n|\leq 2\epsilon/3 < \epsilon $ (by our choice of $ \delta $).

and if

n > N

then

$ \int_A|f_n|\leq \epsilon/3 + \int_A|f_n|^p\leq \epsilon/3 + \int_A|f|^p+\int_A|f_n-f|^p\leq \epsilon/3 + \int_A|f|^p+\int_X|f_n-f|^p\leq \epsilon $.

So $ m(A)<\delta \Rightarrow \int_A|f_n| <\epsilon \ \forall \ n $.

https://balthier.ecn.purdue.edu/index.php/MA544_Qual_Prep_%2708 

--Wardbc 20:17, 1 July 2008 (EDT)Ben Ward
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