(New page: = Homework 8, ECE438, Fall 2010, Prof. Boutin = Due in class, Wednesday November 3, 2010. The discussion page for this homework is here...) |
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== Question 2 == | == Question 2 == | ||
| + | Consider the discrete-time signal | ||
| + | <math>x[n]=6\delta[n]+5 \delta[n-1]+4 \delta[n-2]+3 \delta[n-3]+2 \delta[n-4]+\delta[n-5].</math> | ||
| + | a) Obtain the six-point DFT X[k] of x[n]. | ||
| + | |||
| + | b) Obtain the signal y[n] whose DFT is <math>W_6^{-2k} X[k]</math>. | ||
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Revision as of 10:21, 27 October 2010
Homework 8, ECE438, Fall 2010, Prof. Boutin
Due in class, Wednesday November 3, 2010.
The discussion page for this homework is here.
Question 1
Consider two discrete-time signals with the same (finite) duration N. Let $ X_1(z) $ be the z-transform of the first signal, and $ X_2[k] $ be the N-point DFT of the second signal. If we assume that
$ X_2[k]=\left. X_1(z) \right|_{z=\frac{1}{2}e^{-j \frac{2 \pi}{N} k}}, \text{ for }k=0,1,\ldots,N-1, $
then what is the relationship between the two signals?
Question 2
Consider the discrete-time signal $ x[n]=6\delta[n]+5 \delta[n-1]+4 \delta[n-2]+3 \delta[n-3]+2 \delta[n-4]+\delta[n-5]. $
a) Obtain the six-point DFT X[k] of x[n].
b) Obtain the signal y[n] whose DFT is $ W_6^{-2k} X[k] $.
