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[[Category:2010 Fall ECE 438 Boutin]]
 
[[Category:2010 Fall ECE 438 Boutin]]
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[[Category:Problem_solving]]
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[[Category:ECE438]]
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[[Category:digital signal processing]]
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== Quiz Questions Pool for Week 14 ==
 
== Quiz Questions Pool for Week 14 ==
 
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a. Is this a linear system? Is it space invariant? <br/>
 
a. Is this a linear system? Is it space invariant? <br/>
 
b. What is the 2D impulse response of this system? <br/>
 
b. What is the 2D impulse response of this system? <br/>
c. Calculate its frequency response H(<math>e^{j\mu},e^{j\nu}</math>). <br/>
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c. Calculate its frequency response H(u,v). <br/>
 
d. Describe how the filter behaves when <math>\lambda</math> is positive and large. <br/>
 
d. Describe how the filter behaves when <math>\lambda</math> is positive and large. <br/>
 
e. Describe how the filter behaves when <math>\lambda</math> is negative and bigger than -1. <br/>
 
e. Describe how the filter behaves when <math>\lambda</math> is negative and bigger than -1. <br/>
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* [[ECE438_Week14_Quiz_Q2sol|Solution]].
 
* [[ECE438_Week14_Quiz_Q2sol|Solution]].
 
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Q3. Consider a 3 * 3 FIR filter with coefficients h[m, n]
  
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[[Image:Q3_table.jpg]]
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a. Find a difference equation that can be used to implement this filter.
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b. Given an input image, find the center pixel value of output image.
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[[Image:Q3_inputimg.jpg]]
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c. Find a simple expression for the frequency response (DSFT) H(u,v) of this filter.
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* [[ECE438_Week14_Quiz_Q3sol|Solution]].
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Q4. Consider the following discrete space system with input x[m,n] and output y[m,n]given by
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<math>y[m,n]=x[m,n]+\frac{1}{2}y[m+1,n-1]</math>
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Compute the transfer function
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<math>H(z_1 ,z_2)=\frac{Y(z_1 ,z_2)}{X(z_1 ,z_2)}</math>
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* [[ECE438_Week14_Quiz_Q4sol|Solution]].
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Q5. Consider the following discrete space system
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[[Image:Quiz14Q5.jpg]]
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where <math>b(i,j)</math> is the quantized binary image, <math>f(i,j)</math> is the input and <math>\tilde{f}(i,j)</math> is the modified image by means of the past quantization errors.
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Furthermore we have that
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:<math>\begin{align}e(i,j)&=\tilde{f}(i,j)-b(i,j) \\ \tilde{f}(i,j)&=f(i,j)+H(i,j)\ast e(i,j) \\ \end{align}</math>
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Now, we have <math>H(i,j)=\delta(i-1,j)\,\!</math> is a strictly causal filter and the quantizer <math>Q(\tilde{f})</math> given as
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:<math>Q(\tilde{f})=\left\{ \begin{array}{ll}1,& \tilde{f}(i,j)>0.5 \\ 0, & \tilde{f}(i,j)\leq 0.5 \end{array} \right. </math>
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Assuming that <math>e(i,j)=0</math> for <math>i<0</math> and <math>j<0</math> and the input <math>f(i,j)</math> to be defined as
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[[Image:Quiz14Q5_1.jpg]]
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a. compute the modified input <math>\tilde{f}(i,j)</math>.
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[[Image:Quiz14Q5_2.jpg]]
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b. compute the output <math>b(i,j)</math>.
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[[Image:Quiz14Q5_3.jpg]]
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* [[ECE438_Week14_Quiz_Q5sol|Solution]].
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----
 
Back to [[ECE438_Lab_Fall_2010|ECE 438 Fall 2010 Lab Wiki Page]]
 
Back to [[ECE438_Lab_Fall_2010|ECE 438 Fall 2010 Lab Wiki Page]]
  
 
Back to [[2010_Fall_ECE_438_Boutin|ECE 438 Fall 2010]]
 
Back to [[2010_Fall_ECE_438_Boutin|ECE 438 Fall 2010]]

Latest revision as of 09:43, 11 November 2011


Quiz Questions Pool for Week 14


Q1. Assume we know (or can measure) a function

$ \begin{align} p(x) &= \int_{-\infty}^{\infty}f(x,y)dy \end{align} $

Using the definition of the CSFT, derive an expression for F(u,0) in terms of the function p(x).


Q2. Consider the following 2D system with input x(m,n) and output y(m,n)

$ y(m,n) = x(m,n) + \lambda \left( x(m,n) - \frac{1}{9} \sum_{k=-1}^{1}\sum_{l=-1}^{1}x(m-k,n-l) \right) $

a. Is this a linear system? Is it space invariant?
b. What is the 2D impulse response of this system?
c. Calculate its frequency response H(u,v).
d. Describe how the filter behaves when $ \lambda $ is positive and large.
e. Describe how the filter behaves when $ \lambda $ is negative and bigger than -1.


Q3. Consider a 3 * 3 FIR filter with coefficients h[m, n]

Q3 table.jpg

a. Find a difference equation that can be used to implement this filter.

b. Given an input image, find the center pixel value of output image.

Q3 inputimg.jpg

c. Find a simple expression for the frequency response (DSFT) H(u,v) of this filter.


Q4. Consider the following discrete space system with input x[m,n] and output y[m,n]given by

$ y[m,n]=x[m,n]+\frac{1}{2}y[m+1,n-1] $

Compute the transfer function

$ H(z_1 ,z_2)=\frac{Y(z_1 ,z_2)}{X(z_1 ,z_2)} $


Q5. Consider the following discrete space system

Quiz14Q5.jpg

where $ b(i,j) $ is the quantized binary image, $ f(i,j) $ is the input and $ \tilde{f}(i,j) $ is the modified image by means of the past quantization errors.

Furthermore we have that

$ \begin{align}e(i,j)&=\tilde{f}(i,j)-b(i,j) \\ \tilde{f}(i,j)&=f(i,j)+H(i,j)\ast e(i,j) \\ \end{align} $

Now, we have $ H(i,j)=\delta(i-1,j)\,\! $ is a strictly causal filter and the quantizer $ Q(\tilde{f}) $ given as

$ Q(\tilde{f})=\left\{ \begin{array}{ll}1,& \tilde{f}(i,j)>0.5 \\ 0, & \tilde{f}(i,j)\leq 0.5 \end{array} \right. $

Assuming that $ e(i,j)=0 $ for $ i<0 $ and $ j<0 $ and the input $ f(i,j) $ to be defined as

Quiz14Q5 1.jpg

a. compute the modified input $ \tilde{f}(i,j) $.

Quiz14Q5 2.jpg

b. compute the output $ b(i,j) $.

Quiz14Q5 3.jpg


Back to ECE 438 Fall 2010 Lab Wiki Page

Back to ECE 438 Fall 2010

Alumni Liaison

Correspondence Chess Grandmaster and Purdue Alumni

Prof. Dan Fleetwood