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[[Category:ECE301Spring2011Boutin]] [[Category:Problem_solving]]
 
[[Category:ECE301Spring2011Boutin]] [[Category:Problem_solving]]
 
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= Practice Question on Computing the Fourier Transform of a Continuous-time Signal  =
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= [[:Category:Problem_solving|Practice Question]] on Computing the Fourier Transform of a Continuous-time Signal  =
  
 
Compute the Fourier transform of the signal
 
Compute the Fourier transform of the signal
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Therefore,
 
Therefore,
  
<math>\chi(\omega)=e^{j\omega \frac{\pi}{12}}2\pi \delta(\omega-2\pi k)</math>
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<math>\mathcal X (\omega)=e^{j\omega \frac{\pi}{12}}2\pi \delta(\omega-2\pi k)</math>
  
 
--[[User:Cmcmican|Cmcmican]] 20:52, 21 February 2011 (UTC)
 
--[[User:Cmcmican|Cmcmican]] 20:52, 21 February 2011 (UTC)
  
TA's comments: In the time shift property of the Fourier transform that you provided, it should be <math class="inline">e^{-j\omega t_0}</math> instead. Another thing is that the transform of a cosine should yield only two deltas in the frequency domain.
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:TA's comments: In the time shift property of the Fourier transform that you provided, it should be <math class="inline">e^{-j\omega t_0}</math> and not <math class="inline">e^{j\omega t_0}</math>. Another thing is that the transform of a cosine should yield only two deltas in the frequency domain.
  
 
=== Answer 2  ===
 
=== Answer 2  ===
Write it here.
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I'll try this again, using my new answer from the previous problem, and correcting my time shifting property.
 +
 
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<math>\mathfrak{F}\Bigg(s(t-t_0)\Bigg)=e^{-j\omega t_0}\mathfrak{F}\Bigg(x(t)\Bigg)</math>
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Therefore <math class="inline">\mathcal X (\omega) =e^{-j\omega \frac{\pi}{12}}\Bigg(\pi\delta(\omega-2\pi)+\pi\delta(\omega+2\pi)\Bigg)</math>
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--[[User:Cmcmican|Cmcmican]] 17:43, 23 February 2011 (UTC)
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:TA's comments: You're almost there. You got the transform of the cosine right. However, regarding the time shift property, you still have some mistake in it. Try first to identify what is <math>t_0</math> equal to in this case.
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:Instructor's hint: this has to do with cascading a time shift and a time scaling. Recall that the order of the operation is relevant.-pm
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=== Answer 3  ===
 
=== Answer 3  ===
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Instructor's suggestion: how about writing this as a linear combination of two complex exponentials, and then "guessing" the right transform for each exponential separately (pulling out the constants using linearity of the Fourier transform)? -pm
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Write it here.
 
Write it here.
 
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[[2011_Spring_ECE_301_Boutin|Back to ECE301 Spring 2011 Prof. Boutin]]
 
[[2011_Spring_ECE_301_Boutin|Back to ECE301 Spring 2011 Prof. Boutin]]

Latest revision as of 09:26, 11 November 2011


Practice Question on Computing the Fourier Transform of a Continuous-time Signal

Compute the Fourier transform of the signal

$ x(t) = \cos (2 \pi t+\frac{\pi}{12} )\ $


Share your answers below

You will receive feedback from your instructor and TA directly on this page. Other students are welcome to comment/discuss/point out mistakes/ask questions too!


Answer 1

Use answer to previous practice problem and the time shifting property.

$ \mathfrak{F}\Bigg(s(t-t_0)\Bigg)=e^{j\omega t_0}\mathfrak{F}\Bigg(x(t)\Bigg) $

Therefore,

$ \mathcal X (\omega)=e^{j\omega \frac{\pi}{12}}2\pi \delta(\omega-2\pi k) $

--Cmcmican 20:52, 21 February 2011 (UTC)

TA's comments: In the time shift property of the Fourier transform that you provided, it should be $ e^{-j\omega t_0} $ and not $ e^{j\omega t_0} $. Another thing is that the transform of a cosine should yield only two deltas in the frequency domain.

Answer 2

I'll try this again, using my new answer from the previous problem, and correcting my time shifting property.

$ \mathfrak{F}\Bigg(s(t-t_0)\Bigg)=e^{-j\omega t_0}\mathfrak{F}\Bigg(x(t)\Bigg) $

Therefore $ \mathcal X (\omega) =e^{-j\omega \frac{\pi}{12}}\Bigg(\pi\delta(\omega-2\pi)+\pi\delta(\omega+2\pi)\Bigg) $

--Cmcmican 17:43, 23 February 2011 (UTC)

TA's comments: You're almost there. You got the transform of the cosine right. However, regarding the time shift property, you still have some mistake in it. Try first to identify what is $ t_0 $ equal to in this case.
Instructor's hint: this has to do with cascading a time shift and a time scaling. Recall that the order of the operation is relevant.-pm

Answer 3

Instructor's suggestion: how about writing this as a linear combination of two complex exponentials, and then "guessing" the right transform for each exponential separately (pulling out the constants using linearity of the Fourier transform)? -pm

Write it here.


Back to ECE301 Spring 2011 Prof. Boutin

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