(2 intermediate revisions by one other user not shown)
Line 1: Line 1:
 
[[Category:2010 Fall ECE 438 Boutin]]
 
[[Category:2010 Fall ECE 438 Boutin]]
 
+
[[Category:Problem_solving]]
* Under construction  --[[User:zhao148|Zhao]]
+
[[Category:ECE438]]
 +
[[Category:digital signal processing]]
  
 
== Quiz Questions Pool for Week 11 ==
 
== Quiz Questions Pool for Week 11 ==
Line 56: Line 57:
 
Q5. Define a two-zero band-stop filter such that
 
Q5. Define a two-zero band-stop filter such that
  
There is no gain for constant input.
+
There is a gain 2 for constant input.
 
The filter has a zero frequency response at <math>\omega=\frac{\pi}{2}</math>.
 
The filter has a zero frequency response at <math>\omega=\frac{\pi}{2}</math>.
 
Express the system using a constant coefficient difference equation.
 
Express the system using a constant coefficient difference equation.

Latest revision as of 09:42, 11 November 2011


Quiz Questions Pool for Week 11


Q1. Consider the two LTI systems, $ y[n]=T_1[x[n]] $ and $ y[n]=T_2[x[n]] $, with the following difference equations,

$ y[n]=T_1[x[n]]=x[n]-x[n-1]\,\! $
$ y[n]=T_2[x[n]]=\frac{1}{2}y[n-1]+x[n]\,\! $

Then, calculate the impulse response and difference equation of the combined system $ (T_1+T_2)[x[n]] $.


Q2. Consider a causal FIR filter of length M = 2 with impulse response

$ h[n]=\delta[n]-\delta[n-1]\,\! $

a) Provide a closed-form expression for the 8-pt DFT of $ h[n] $, denoted $ H_8[k] $, as a function of $ k $. Simplify as much as possible.

b) Consider the sequence $ x[n] $ of length 8 below,

$ x[n]=\text{cos}(\pi n)(u[n]-u[n-8])\,\! $

$ y_8[n] $ is formed by computing $ X_8[k] $ as an 8-pt DFT of $ x[n] $, $ H_8[k] $ as an 8-pt DFT of $ h[n] $, and then $ y_8[n] $ as the 8-pt inverse DFT of $ Y_8[k] = X_8[k]H_8[k] $.

Express the result $ y_8[n] $ as a weighted sum of finite-length sinewaves similar to how $ x[n] $ is written above.


Q3. 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).


  • Same as HW7, Q4 available here.

Q4. Given the impulse response, compute the transfer function of filters.

$ x_1[n]=(\frac{1}{2})^nu[n]+2^nu[-n-1] $

$ x_2[n]=6(\frac{1}{2})^nu[n]-6(\frac{3}{4})^nu[n] $

Are the systems stable? Why or why not?


Q5. Define a two-zero band-stop filter such that

There is a gain 2 for constant input. The filter has a zero frequency response at $ \omega=\frac{\pi}{2} $. Express the system using a constant coefficient difference equation.


Back to ECE 438 Fall 2010 Lab Wiki Page

Back to ECE 438 Fall 2010

Alumni Liaison

Followed her dream after having raised her family.

Ruth Enoch, PhD Mathematics