Difference between revisions of "Exam 9.1 Old Kiwi" - Rhea

Revision as of 14:18, 22 July 2008

a) $|h(x)| \leq (\int |f(x-y)|^p dy)^{1/p}(\int |g(y)|^q dy)^{1/q} = (\int |f(z)|^p dz)^{1/p}(\int |g(y)|^q dy)^{1/q} \leq ||f||_{p}||g||_{q}$

b)Define $f_{t}(x)=f(x+t)\frac{}{}$ , $h_{t}(x)=h(x+t)\frac{}{}$ .

We have

$|h_{t}(x) - h(x)| = |\int[f_t(x-y)-f(x-y)]g(y)dy |$

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 a)<math>|h(x)| \leq (\int |f(x-y)|^p dy)^{1/p}(\int |g(y)|^q dy)^{1/q} = (\int |f(z)|^p dz)^{1/p}(\int |g(y)|^q dy)^{1/q} \leq ||f||_{p}||g||_{q}</math>
-b)Define <math>f_{t}(x)=f(x-t)\frac{}{}</math>, <math>h_{t}(x)=h(x-t)\frac{}{}</math>
+b)Define <math>f_{t}(x)=f(x+t)\frac{}{}</math>, <math>h_{t}(x)=h(x+t)\frac{}{}</math>.
+We have
+<math>|h_{t}(x) - h(x)| =  |\int[f_t(x-y)-f(x-y)]g(y)dy |</math>