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<math>\leq\int_{\{|f-f_n|>\epsilon\}}|f|+\int_{|f|>M-\epsilon}|f|</math> | <math>\leq\int_{\{|f-f_n|>\epsilon\}}|f|+\int_{|f|>M-\epsilon}|f|</math> | ||
| − | <math>f_n\to | + | <math>f_n\to f(L_1)=>f_n\to f(in measure)</math> |
Revision as of 10:17, 2 July 2008
$ \sup\limits_n\int_{\{|f_n|>M\}}|f_n|\leq\sup\limits_n\int_{(0,1)}|f_n-f|+\sup\limits_n\int_{\{|f_n|>M\}}|f| $
$ Since \int_{(0,1)}|f_n-f|\to0(n\to\infty), \sup\limits_n\int_{(0,1)}|f_n-f|=0 $
Therefore, to show $ \sup\limits_n\int_{\{|f_n|>M\}}|f_n|\to0(M\to\infty), $it suffices to show that $ \sup\limits_n\int_{\{|f_n|>M\}}|f|\to0(M\to\infty) $
Actually,
$ \int_{\{f_n>M\}}|f|\leq\int_{\{|f_n|>M,|f|<M-\epsilon\}}|f|+\int_{\{|f|>M-\epsilon\}}|f| $
$ \leq\int_{\{|f-f_n|>\epsilon\}}|f|+\int_{|f|>M-\epsilon}|f| $
$ f_n\to f(L_1)=>f_n\to f(in measure) $
