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:a.  Find the difference equation of this filter.
 
:a.  Find the difference equation of this filter.
  
:b.  Find the frequency response <math>H(w)</math> by the following two approaches:
+
:b.  Find the frequency response <math>H(w)</math> from the difference equation by the following two approaches:
 
::i.  apply the input <math>e^{jwn}</math> to the difference equation describing the system,
 
::i.  apply the input <math>e^{jwn}</math> to the difference equation describing the system,
 
::ii.  find the DTFT of the impulse response,
 
::ii.  find the DTFT of the impulse response,

Revision as of 10:25, 19 October 2010



Quiz Questions Pool for Week 9


Q1. Consider the following second order FIR filter with the two zeros on the unit circle as shown below.

Quiz9Q1.jpg

The transfer function for this filter is given by $ H(z) = (1-e^{j\theta}z^{-1})(1-e^{-j\theta}z^{-1})=1-2\cos\theta z^{-1}+z^{-2} $

a. Find the difference equation of this filter.
b. Find the frequency response $ H(w) $ from the difference equation by the following two approaches:
i. apply the input $ e^{jwn} $ to the difference equation describing the system,
ii. find the DTFT of the impulse response,
and verify that both methods lead to the same result.
c. Find the response of this system to the input
$ x[n]=\left\{ \begin{array}{rl} 1, & \text{ if }n=-2,\\ 1, & \text{ if }n=0,\\ 1, & \text{ if }n=2,\\ 0, & \text{ else. } \end{array} \right. $
d. Is this filter a lowpass, highpass, bandpass or a bandstop filter?
e. An interference signal modulated at 2kHz and sampled at 8kHz is being inputted to this system and you want to eliminate this interference. What must be the value of $ \theta $ to eliminate this signal?

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Back to ECE 438 Fall 2010 Lab Wiki Page

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Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva