(New page: # <math>\log ||f||_p=\log \left(\int |f|^p\right)^{1/p}=\frac{1}{p}\log\left(\int|f|^p\right)\geq\frac{1}{p}\int\log|f|^p=\int\log|f|d\mu</math> The last but two inequality is due to the...)
 
 
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First inequality is by <math>log(x)\leq x-1</math> from hint; the second equality is due to the property of probability space<math>\int d\mu=1</math>
 
First inequality is by <math>log(x)\leq x-1</math> from hint; the second equality is due to the property of probability space<math>\int d\mu=1</math>
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By L' Hospital Rule,<math>\phi(p)=\frac{|f|^p-1}{p}\to log|f|,(p\to0)</math>
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Since <math>\phi(p)</math> is monotone increasing, by Monotone Convergence Theorem, <math>\int\frac{|f|^p-1}{p}\to\int\log|f|d\mu</math>
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Therefore,<math>\lim\limits_{p\to0}\log||f||_p=\int_X\log|f|d\mu</math>, and the result follows by using Exp on the both sides.

Latest revision as of 10:15, 10 July 2008

$ \log ||f||_p=\log \left(\int |f|^p\right)^{1/p}=\frac{1}{p}\log\left(\int|f|^p\right)\geq\frac{1}{p}\int\log|f|^p=\int\log|f|d\mu $

The last but two inequality is due to the integral form of Jensen's inequality.

$ \log||f||_p=\frac{1}{p}\log\left(\int|f|^p\right)\leq\frac{1}{p}\left(\int|f|^p-1\right)=\frac{1}{p}\int(|f|^p-1)=\int\frac{|f|^p-1}{p} $

First inequality is by $ log(x)\leq x-1 $ from hint; the second equality is due to the property of probability space$ \int d\mu=1 $

By L' Hospital Rule,$ \phi(p)=\frac{|f|^p-1}{p}\to log|f|,(p\to0) $

Since $ \phi(p) $ is monotone increasing, by Monotone Convergence Theorem, $ \int\frac{|f|^p-1}{p}\to\int\log|f|d\mu $

Therefore,$ \lim\limits_{p\to0}\log||f||_p=\int_X\log|f|d\mu $, and the result follows by using Exp on the both sides.

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang