User:GabrielaV: Difference between revisions
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== Fourier Transform== |
== Fourier Transform== |
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As previously discussed Fourier |
As previously discussed, ''Fourier series'' is an expansion of a periodic function therefore we can not use it to transform a non-periodic funciton from time to the frequency domain. Fortunately the ''Fourier'' ''transform'' allows for the transformation to be done on a non-periodic function. |
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In order to understand the relationship between a non-periodic function and it's counterpart we must go back to |
In order to understand the relationship between a non-periodic function and it's counterpart we must go back to ''Fourier series''. Remember the complex exponential signal? |
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[http://cubex.wwc.edu/~frohro/wiki/index.php/Fourier_series#Periodic_Functions] |
[http://cubex.wwc.edu/~frohro/wiki/index.php/Fourier_series#Periodic_Functions] |
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The summation becomes integration, the harmoinic frequency becomes a continuous frequency, and the incremental spacing becomes a differential separation. |
The summation becomes integration, the harmoinic frequency becomes a continuous frequency, and the incremental spacing becomes a differential separation. |
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::<math> {sum_k=-\infty}^\infty\to\int_{-\infty}^\infty</math> |
::<math> {sum_k=-\infty}^\infty\to\int_{-\infty}^\infty</math> |
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::<math> {k\over T\to\f}</math> |
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::<math> {1/T\to\df}</math> |
Revision as of 21:11, 13 October 2005
Welcome to Gabriela's Wiki page
Introduction
Do you want to know how to contact me or find out some interesting things about me? [[1]]
Signals & Systems
Example
Find the first two orthogonormal polynomials on [-1,1]
1. What is orthogonormal? [2]
2. What is orthogonal? [3]
3. What is a polynomial? [4]
4. Now we can find the values for the unknown variables.
5. Now that we know what the first two orthogonormal polynomials!
Fourier Transform
As previously discussed, Fourier series is an expansion of a periodic function therefore we can not use it to transform a non-periodic funciton from time to the frequency domain. Fortunately the Fourier transform allows for the transformation to be done on a non-periodic function.
In order to understand the relationship between a non-periodic function and it's counterpart we must go back to Fourier series. Remember the complex exponential signal?
[5]
where
If we let
The summation becomes integration, the harmoinic frequency becomes a continuous frequency, and the incremental spacing becomes a differential separation.