(New page: Category:MA5530Spring2014Bell Category:MA530 Category:math Category:homework == Homework 2 collaboration area == Here it is again: <math>f(a)=\frac{1}{2\pi i}\int_\gam...)
 
(Started Discussion of Problem 1)
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'''Exercise 1'''
  
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Suppose that <math>\varphi(z)</math> is a continuous function on the trace of a path <math>\gamma</math>. Prove that the function
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<math>f(z)=\int_{\gamma}\frac{\varphi(\zeta)}{\zeta-z}d\zeta</math>
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is analytic on <math>\mathbb{C}-\text{tr }\gamma</math>.
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'''Discussion'''
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-A function is said to be analytic on an open set <math>\Omega</math> if it is <math>\mathbb{C}</math>-differentiable at every point in <math>\Omega</math>. Since the definition of analytic involves an open set, to complete Exercise 1 we need to have an open set somewhere. Since <math>\text{tr }\gamma</math> is the continuous image of a compact set, it is compact. Since <math>\mathbb{C}</math> is a Hausdorff space, <math>\text{tr }\gamma</math> is closed. Alternately one can note that <math>\mathbb{C}</math> is homeomorphic to <math>\mathbb{R}^{2}</math> where we know that a compact set is closed and bounded. Since the complement of a closed set is open, <math>\mathbb{C}-\text{tr }\gamma</math> is open. The long and short of this is: <math>\mathbb{C}-\text{tr }\gamma</math> is an open set so one just has to show that <math>\varphi</math> is <math>\mathbb{C}</math>-differentiable at every point in this set in order to complete the exercise.
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Revision as of 19:09, 28 January 2014


Homework 2 collaboration area

Here it is again:

$ f(a)=\frac{1}{2\pi i}\int_\gamma \frac{f(z)}{z-a}\ dz. $


This is the place.


Exercise 1

Suppose that $ \varphi(z) $ is a continuous function on the trace of a path $ \gamma $. Prove that the function

$ f(z)=\int_{\gamma}\frac{\varphi(\zeta)}{\zeta-z}d\zeta $

is analytic on $ \mathbb{C}-\text{tr }\gamma $.


Discussion

-A function is said to be analytic on an open set $ \Omega $ if it is $ \mathbb{C} $-differentiable at every point in $ \Omega $. Since the definition of analytic involves an open set, to complete Exercise 1 we need to have an open set somewhere. Since $ \text{tr }\gamma $ is the continuous image of a compact set, it is compact. Since $ \mathbb{C} $ is a Hausdorff space, $ \text{tr }\gamma $ is closed. Alternately one can note that $ \mathbb{C} $ is homeomorphic to $ \mathbb{R}^{2} $ where we know that a compact set is closed and bounded. Since the complement of a closed set is open, $ \mathbb{C}-\text{tr }\gamma $ is open. The long and short of this is: $ \mathbb{C}-\text{tr }\gamma $ is an open set so one just has to show that $ \varphi $ is $ \mathbb{C} $-differentiable at every point in this set in order to complete the exercise.


Back to MA530, Spring 2014

Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva