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:b. Find the impulse response h[n] and convolve it with x[n];  
 
:b. Find the impulse response h[n] and convolve it with x[n];  
 
:c. Find the frequency response by the following two approaches:  
 
:c. Find the frequency response by the following two approaches:  
::i. apply the input<math> e^{ j n}</math> to the difference equation describing the system,  
+
::i. apply the input <math> e^{ j n}</math> to the difference equation describing the system,  
 
::ii. find the DTFT of the impulse response.  
 
::ii. find the DTFT of the impulse response.  
 
:(verify that both methods lead to the same result) then find the DTFT of the input, multiply it by the frequency response of the system to yield the DTFT of the output, and finally calculate the inverse DTFT y[n].  
 
:(verify that both methods lead to the same result) then find the DTFT of the input, multiply it by the frequency response of the system to yield the DTFT of the output, and finally calculate the inverse DTFT y[n].  
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<math>
 
<math>
H(z)= \frac{1-  
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H(z)= \frac{1-\frac{1}{2}z^{-2}}
1  
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{1-\frac{1}{\sqrt{2}} z^{-1} +\frac{1}{4} z^{-2}}
2z
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</math>  
!2 }
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{1!1  
+
2z
+
!1  
+
+1  
+
4z
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!2 } </math>  
+
  
 
:a. Sketch the locations of the poles and zeros.  
 
:a. Sketch the locations of the poles and zeros.  
:b. Use the graphical approach to determine the magnitude and phase of the  
+
:b. Determine the magnitude and phase of the frequency response <math>H(\omega)</math>, for  
frequency response H(!), for !=0,"/4, "/2, 3"/4,and ". Based on
+
 
these values, sketch the magnitude and phase of the frequency response for
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::<math>\omega =0,\frac{\pi}{4}, \frac{\pi}{2}, \frac{3\pi}{4}, \text{ and }\pi</math>.  
!"#$#". (Be sure to show your work.)
+
 
:c. Is the system stable, Explain why or why not?  
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:c. Is the system stable? Explain why or why not?  
 
:d. Find the difference equation for y[n] in terms of x[n], corresponding to this transfer function H(z).  
 
:d. Find the difference equation for y[n] in terms of x[n], corresponding to this transfer function H(z).  
  
 
----
 
----
 +
==Question 5 ==
 
Consider a DT LTI system described by the following non-recursive difference  
 
Consider a DT LTI system described by the following non-recursive difference  
 
equation (moving average filter)  
 
equation (moving average filter)  
y[n]=1  
+
 
8 x[n]+x[n!1]+x[n!2]+x[n!3]+x[n!4]+x[n!5]+x[n!6]+x[n!7]  
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<math>
{ }
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y[n]=\frac{1}{8} \left( x[n]+x[n-1]+x[n-2]+x[n-3]+x[n-4]+x[n-5]+x[n-6]+x[n-7]\right)
a. Find the impulse response h[n] for this filter.  Is it of finite or infinite  
+
</math>
duration?  
+
b. Find the transfer function H(z) for this filter.  
+
:a. Find the impulse response h[n] for this filter.  Is it of finite or infinite duration?  
c. Sketch the locations of poles and zeros in the complex z-plane.  
+
:b. Find the transfer function H(z) for this filter.  
Hint:  To factor H(z), use the geometric series and the fact that the roots of the  
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: c. Sketch the locations of poles and zeros in the complex z-plane.  
polynomial z
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Hint:  To factor H(z), use the geometric series and the fact that the roots of the polynomial  
N  
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<math>z^N- p_0 =0</math>
!p0 =0 are given by  
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are given by  
 
+
 
z
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<math> 
k =p0
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z_k =|p_0|^{\frac{1}{N}} e^{j \frac{(\text{arg }p_0+2\pi k)}{N}}
1/ N  
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,\quad k=0,\ldots ,N-1</math>
e  
+
----
j (argp
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==Question 6 ==
0)/N+2!k/ N  
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Consider a DT LTI system described by the following recursive  difference  
[ ]
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,k=0,K,N"1  
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4. Consider a DT LTI system described by the following recursive  difference  
+
 
equation  
 
equation  
  y[n]=  
+
 
1  
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<math>
8 x[n]!x[n!8]  
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  y[n]= \frac{1}{8} \left( x[n]-x[n-8] \right) +y[n-1] </math>
{ }+y[n!1]  
+
 
a. Find the transfer function H(z) for this filter.  
+
:a. Find the transfer function H(z) for this filter.  
b. Sketch the locations of poles and zeros in the complex z-plane.  
+
:b. Sketch the locations of poles and zeros in the complex z-plane.  
Hint:  See Part c of Problem 3.  
+
::Hint:  See Part c of the previous problem.  
c. Find the impulse response h[n] for this filter by computing the inverse ZT of  
+
:c. Find the impulse response h[n] for this filter by computing the inverse ZT of H(z).  Is it of finite or infinite duration?  
H(z).  Is it of finite or infinite duration?  
+
  
 
----
 
----
 
[[2010 Fall ECE 438 Boutin|Back to ECE438, Fall 2010, Prof. Boutin]]
 
[[2010 Fall ECE 438 Boutin|Back to ECE438, Fall 2010, Prof. Boutin]]

Latest revision as of 10:22, 30 October 2011

Homework 7, ECE438, Fall 2010, Prof. Boutin

Due in class, Friday October 22, 2010.

The discussion page for this homework is here.


Question 1

Compute the discrete Fourier transform of the following discrete-time signals:

$ x_1[n]= e^{j \frac{2}{3} \pi n}; $
$ x_2[n]= e^{j \frac{2}{\sqrt{3}} \pi n}; $
$ x_3[n]= e^{j \frac{4}{3} \pi n}; $
$ x_4[n]= e^{j \frac{2}{1000} \pi n}; $
$ x_5[n]= e^{-j \frac{2}{1000} \pi n}; $
$ x_6[n]= \cos\left( \frac{2}{1000} \pi n\right) ; $
$ x_7[n]= \cos^2\left( \frac{2}{1000} \pi n\right) ; $.
$ x_8[n]= (-j)^n . $

How do your answers relate to the Fourier series coefficients of x[n]?


Question 2

Obtain the frequency response and the transfer function for each of the following systems:

$ y_1[n]= \frac{x[n]+x[n-1]}{2}; $
$ y_2[n]= \frac{x[n]-x[n-1]}{2}; $
$ y_3[n]= \frac{x[n+1]+x[n]+x[n-1]}{3}; $
$ y_4[n]= \frac{x[n+1]-2 x[n]+x[n-1]}{4}. $

Question 3

Consider a DT LTI system described by the following equation

$ y[n]=x[n]+2x[n-1]+x[n-2]. $

Find the response of this system to the input

$ x[n]=\left\{ \begin{array}{rl} -2, & \text{ if }n=-2,\\ 1, & \text{ if }n=0,\\ -2 & \text{ if }n=2,\\ 0, & \text{ else. } \end{array} \right. $

by the following approaches:

a. Directly substitute x[n] into the difference equation describing the system;
b. Find the impulse response h[n] and convolve it with x[n];
c. Find the frequency response by the following two approaches:
i. apply the input $ e^{ j n} $ to the difference equation describing the system,
ii. find the DTFT of the impulse response.
(verify that both methods lead to the same result) then find the DTFT of the input, multiply it by the frequency response of the system to yield the DTFT of the output, and finally calculate the inverse DTFT y[n].
d. Verify that all three approaches for finding y[n] lead to the same result.

Question 4

Consider a causal LTI system with transfer function

$ H(z)= \frac{1-\frac{1}{2}z^{-2}} {1-\frac{1}{\sqrt{2}} z^{-1} +\frac{1}{4} z^{-2}} $

a. Sketch the locations of the poles and zeros.
b. Determine the magnitude and phase of the frequency response $ H(\omega) $, for
$ \omega =0,\frac{\pi}{4}, \frac{\pi}{2}, \frac{3\pi}{4}, \text{ and }\pi $.
c. Is the system stable? Explain why or why not?
d. Find the difference equation for y[n] in terms of x[n], corresponding to this transfer function H(z).

Question 5

Consider a DT LTI system described by the following non-recursive difference equation (moving average filter)

$ y[n]=\frac{1}{8} \left( x[n]+x[n-1]+x[n-2]+x[n-3]+x[n-4]+x[n-5]+x[n-6]+x[n-7]\right) $

a. Find the impulse response h[n] for this filter. Is it of finite or infinite duration?
b. Find the transfer function H(z) for this filter.
c. Sketch the locations of poles and zeros in the complex z-plane.

Hint: To factor H(z), use the geometric series and the fact that the roots of the polynomial $ z^N- p_0 =0 $ are given by

$ z_k =|p_0|^{\frac{1}{N}} e^{j \frac{(\text{arg }p_0+2\pi k)}{N}} ,\quad k=0,\ldots ,N-1 $


Question 6

Consider a DT LTI system described by the following recursive difference equation

$ y[n]= \frac{1}{8} \left( x[n]-x[n-8] \right) +y[n-1] $

a. Find the transfer function H(z) for this filter.
b. Sketch the locations of poles and zeros in the complex z-plane.
Hint: See Part c of the previous problem.
c. Find the impulse response h[n] for this filter by computing the inverse ZT of H(z). Is it of finite or infinite duration?

Back to ECE438, Fall 2010, Prof. Boutin

Alumni Liaison

BSEE 2004, current Ph.D. student researching signal and image processing.

Landis Huffman