m (Fourier Series)
 
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[[Homework 4_ECE301Fall2008mboutin|<< Back to Homework 4]]
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[[Category:problem solving]]
 
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[[Category:ECE301]]
Homework 4 Ben Horst:  [[HW4.1 Ben Horst _ECE301Fall2008mboutin| 4.1]] ::  [[HW4.2 Ben Horst _ECE301Fall2008mboutin| 4.2]] ::  [[HW4.3 Ben Horst _ECE301Fall2008mboutin| 4.3]]::  [[HW4.4 Ben Horst _ECE301Fall2008mboutin| 4.4]]::  [[HW4.5 Ben Horst _ECE301Fall2008mboutin| 4.5]]
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[[Category:ECE]]
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[[Category:Fourier series]]
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[[Category:signals and systems]]
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== Example of Computation of Fourier series of a CT SIGNAL ==
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A [[Signals_and_systems_practice_problems_list|practice problem on "Signals and Systems"]]
 
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[[Homework 4_ECE301Fall2008mboutin|<< Back to Homework 4]]
 
[[Homework 4_ECE301Fall2008mboutin|<< Back to Homework 4]]
  
Homework 4 Ben Horst:  [[HW4.1 Ben Horst _ECE301Fall2008mboutin| 4.1]] :: [[HW4.2 Ben Horst _ECE301Fall2008mboutin| 4.2]]  ::  [[HW4.3 Ben Horst _ECE301Fall2008mboutin| 4.3]]::  [[HW4.4 Ben Horst _ECE301Fall2008mboutin| 4.4]]::  [[HW4.5 Ben Horst _ECE301Fall2008mboutin| 4.5]]
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Homework 4 Ben Horst:  [[HW4.1 Ben Horst _ECE301Fall2008mboutin| 4.1]] :: [[HW4.3 Ben Horst _ECE301Fall2008mboutin| 4.3]] ::  [[HW4.5 Ben Horst _ECE301Fall2008mboutin| 4.5]]
 
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==Signal==
 
==Signal==
x(t) = 2sin(6t) + 4cos(3t)
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<math>x(t) = 2\sin(6t) + 4\cos(3t)</math>
  
 
==Fourier Series==
 
==Fourier Series==
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By Euler's formula, we have:
 
By Euler's formula, we have:
 
<math>
 
<math>
x(t)=2({ e^{j 6t} + -e^{-j6t} \over 2j}) + 4({ e^{j 6t} + e^{-j6t} \over 2})
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x(t)=2({ e^{j 6t} + -e^{-j6t} \over 2j}) + 4({ e^{j3t} + e^{-j3t} \over 2 })
 
</math>
 
</math>
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<math>
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x(t) = ({ e^{j 6t} + -e^{-j6t} \over j}) + 2e^{j3t} + 2e^{-j3t}
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</math>
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<math>
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x(t) = -e^{2 j3t} + e^{-2 j3t} + 2e^{1 j3t} + 2e^{-1 j3t}
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</math>
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Ordering our k's to form a proper series:
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<math>
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x(t)= e^{(-2) j3t} + 2e^{(-1)j3t} + 2e^{(1) j3t} - e^{(2) j3t}
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</math>
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And making sure we don't forget about  <math>a_0</math>:
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<math>
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x(t)= (1)e^{(-2) j3t} + (2)e^{(-1)j3t} + (0)e^{(0)j3t} + (2)e^{(1) j3t} + (-1)e^{(2) j3t}
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</math>
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==Summary==
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From the above math, we can determine all the coefficients:
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<math> \ \ a_{-2} = 1; \ \ a_{-1} = 2; \ \ a_{0} = 0; \ \  a_1 = 2;\ \ a_{2} = -1 </math>
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The fundamental period of the function is found from: <math>e^{j\omega_0}</math> where he period T = <math>{2\pi \over \omega_o}</math>
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Thus, the fundamental period = <math> {2\pi \over 3} </math>
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[[Signals_and_systems_practice_problems_list|Back to Practice Problems on Signals and Systems]]

Latest revision as of 09:54, 16 September 2013

Example of Computation of Fourier series of a CT SIGNAL

A practice problem on "Signals and Systems"



<< Back to Homework 4

Homework 4 Ben Horst: 4.1 :: 4.3 :: 4.5


Signal

$ x(t) = 2\sin(6t) + 4\cos(3t) $

Fourier Series

$ x(t) = \sum_{k=- \infty }^ \infty a_ke^{jk\omega_0t} $

By Euler's formula, we have: $ x(t)=2({ e^{j 6t} + -e^{-j6t} \over 2j}) + 4({ e^{j3t} + e^{-j3t} \over 2 }) $

$ x(t) = ({ e^{j 6t} + -e^{-j6t} \over j}) + 2e^{j3t} + 2e^{-j3t} $

$ x(t) = -e^{2 j3t} + e^{-2 j3t} + 2e^{1 j3t} + 2e^{-1 j3t} $

Ordering our k's to form a proper series:

$ x(t)= e^{(-2) j3t} + 2e^{(-1)j3t} + 2e^{(1) j3t} - e^{(2) j3t} $

And making sure we don't forget about $ a_0 $:

$ x(t)= (1)e^{(-2) j3t} + (2)e^{(-1)j3t} + (0)e^{(0)j3t} + (2)e^{(1) j3t} + (-1)e^{(2) j3t} $

Summary

From the above math, we can determine all the coefficients: $ \ \ a_{-2} = 1; \ \ a_{-1} = 2; \ \ a_{0} = 0; \ \ a_1 = 2;\ \ a_{2} = -1 $

The fundamental period of the function is found from: $ e^{j\omega_0} $ where he period T = $ {2\pi \over \omega_o} $

Thus, the fundamental period = $ {2\pi \over 3} $


Back to Practice Problems on Signals and Systems

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