| Line 4: | Line 4: | ||
---- | ---- | ||
Q1. Consider a causal FIR filter of length M = 2 with impulse response | Q1. Consider a causal FIR filter of length M = 2 with impulse response | ||
| − | :<math>h[n]=\delta[n]+\delta[n- | + | :<math>h[n]=\delta[n-1]+\delta[n-2]\,\!</math> |
a) Provide a closed-form expression for the 9-pt DFT of <math>h[n]</math>, denoted <math>H_9[k]</math>, as a function of <math>k</math>. Simplify as much as possible. | a) Provide a closed-form expression for the 9-pt DFT of <math>h[n]</math>, denoted <math>H_9[k]</math>, as a function of <math>k</math>. Simplify as much as possible. | ||
b) Consider the sequence <math>x[n]</math> of length 9 below, | b) Consider the sequence <math>x[n]</math> of length 9 below, | ||
| − | :<math>x[n]=\text{cos}\left(\frac{\pi}{3}n\right)(u[n]-u[n-9])\,\!</math> | + | :<math>x[n]=\text{cos}\left(\frac{2\pi}{3}n\right)(u[n]-u[n-9])\,\!</math> |
<math>y_9[n]</math> is formed by computing <math>X_9[k]</math> as an 9-pt DFT of <math>x[n]</math>, <math>H_9[k]</math> as an 9-pt DFT of <math>h[n]</math>, and then <math>y_9[n]</math> as the 9-pt inverse DFT of <math>Y_9[k] = X_9[k]H_9[k]</math>. | <math>y_9[n]</math> is formed by computing <math>X_9[k]</math> as an 9-pt DFT of <math>x[n]</math>, <math>H_9[k]</math> as an 9-pt DFT of <math>h[n]</math>, and then <math>y_9[n]</math> as the 9-pt inverse DFT of <math>Y_9[k] = X_9[k]H_9[k]</math>. | ||
Revision as of 02:09, 9 November 2010
Quiz Questions Pool for Week 12
Q1. Consider a causal FIR filter of length M = 2 with impulse response
- $ h[n]=\delta[n-1]+\delta[n-2]\,\! $
a) Provide a closed-form expression for the 9-pt DFT of $ h[n] $, denoted $ H_9[k] $, as a function of $ k $. Simplify as much as possible.
b) Consider the sequence $ x[n] $ of length 9 below,
- $ x[n]=\text{cos}\left(\frac{2\pi}{3}n\right)(u[n]-u[n-9])\,\! $
$ y_9[n] $ is formed by computing $ X_9[k] $ as an 9-pt DFT of $ x[n] $, $ H_9[k] $ as an 9-pt DFT of $ h[n] $, and then $ y_9[n] $ as the 9-pt inverse DFT of $ Y_9[k] = X_9[k]H_9[k] $.
Express the result $ y_9[n] $ as a weighted sum of finite-length sinewaves similar to how $ x[n] $ is written above.
Q2.
Q3.
Q4.
Q5.
Back to ECE 438 Fall 2010 Lab Wiki Page
Back to ECE 438 Fall 2010
