Latest revision as of 03:55, 31 August 2013

Homework 4, ECE438, Fall 2011, Prof. Boutin

Due Wednesday October 5, 2011 (in class)

Compute the DFT of the following signals

a) $x_1[n] = \left\{ \begin{array}{ll} 1, & n \text{ multiple of } N\\ 0, & \text{ else}. \end{array} \right.$

b) $x_2[n]= e^{j \frac{\pi}{3} n } \cos ( \frac{\pi}{6} n )$

c) $x_3[n] =(\frac{1}{\sqrt{2}}+j \frac{1}{\sqrt{2}})^n$

Compute the inverse DFT of $X[k]= e^{j \pi k }+e^{-j \frac{\pi}{2} k}$ .

Under which circumstances can one explicitly reconstruct the DTFT of a finite duration signal from its DFT? Justify your answer mathematically.

Prove the time shifting property of the DFT.

Write your questions/comments here

Note: When asked to compute DFT of a periodic signal x[n], just use the fundamental period of x[n] as N. Same thing for the inverse DFT. -pm

For Q1,b and c, can we just list the complex exponential and say "by comparing to the DFT pairs we can get the answer X[k]=blah" ?

Yes, you should! -pm

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+[[Category:ECE438Fall2011Boutin]]
+[[Category:ECE438]]
+[[Category:ECE]]
+[[Category:signal processing]]
+[[Category:homework]]
 =Homework 4, [[ECE438]], Fall 2011, [[user:mboutin|Prof. Boutin]]=
 Due Wednesday October 5, 2011 (in class)
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 Compute the DFT of the following signals
-b) <math class="inline">
+a) <math class="inline">
 x_1[n] = \left\{
 \begin{array}{ll}
@@ Line 14: / Line 20: @@
 </math>
-a) <math class="inline">x_2[n]= e^{j \frac{\pi}{3} n } \cos ( \frac{\pi}{6} n )</math>
+b) <math class="inline">x_2[n]= e^{j \frac{\pi}{3} n } \cos ( \frac{\pi}{6} n )</math>
@@ Line 36: / Line 42: @@
 *Note: When asked to compute DFT of a periodic signal x[n], just use the fundamental period of x[n] as N. Same thing for the inverse DFT. -pm
+For Q1,b and c, can we just list the complex exponential and say "by comparing to the DFT pairs we can get the answer X[k]=blah" ?
+:Yes, you should! -pm
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