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* [[Media:Qpw12ece438fa10.pdf|Solution]]. | * [[Media:Qpw12ece438fa10.pdf|Solution]]. | ||
---- | ---- | ||
| − | Q4. | + | Q4. Consider the STDTFT defined as |
| + | |||
| + | <math>X(\omega ,n)=\sum_k x[k]w[n-k]e^{-j\omega k}</math> | ||
| + | |||
| + | where x[n] is the speech signal and w[n] is the window sequence. Prove the following properties: | ||
| + | |||
| + | a. Linearity – if <math>v[n]=ax[n]+by[n]</math> ,then <math>V(\omega ,n)=aX(\omega ,n)+bY(\omega, n)</math>. | ||
| + | |||
| + | b. Modulation – if <math>v[n]=x[n]e^{j\omega_0n}</math> ,then <math>V(\omega ,n)=X(\omega -\omega_0,n)</math>. | ||
* [[ECE438_Week12_Quiz_Q4sol|Solution]]. | * [[ECE438_Week12_Quiz_Q4sol|Solution]]. | ||
---- | ---- | ||
| − | Q5. | + | Q5. Suppose we have two 4-pt sequences x[n] and h[n] described as follows: |
| + | |||
| + | <math> | ||
| + | \begin{align} | ||
| + | x[n] &= cos(\frac{\pi n}{2})\text{ ,n=0,1,2,3} \\ | ||
| + | h[n] &= 2^n\text{ ,n=0,1,2,3} | ||
| + | \end{align} | ||
| + | </math> | ||
* [[ECE438_Week12_Quiz_Q5sol|Solution]]. | * [[ECE438_Week12_Quiz_Q5sol|Solution]]. | ||
Revision as of 12:50, 10 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. Consider the discrete-time signal
- $ x[n]=6\delta[n]+5 \delta[n-1]+4 \delta[n-2]+3 \delta[n-3]+2 \delta[n-4]+\delta[n-5]. $
a) Obtain the 6-point DFT X[k] of x[n].
b) Obtain the signal y[n] whose DFT is $ W_6^{-2k} X[k] $.
c) Compute six-point circular convolution between x[n] and the signal
- $ h[n]=\delta[n]+\delta[n-1]+\delta[n-2]. $
- Same as HW8, Q2 available Solution.
Q3. Consider the signal
$ x[n] = \begin{cases} cos(\pi n / 8), & n < 0 \\ cos(\pi n / 3), & \mbox{else} \end{cases} $
and assume a rectangular window
$ w[n] = \begin{cases} 1, & |n| < 25 \\ 0, & \mbox{else} \end{cases} $
The STDFT is defined as
$ \begin{align} X(\omega,n) &= \sum_{k} x[k]w[n-k]e^{-j\omega k} \end{align} $
Compute the STDTFT for the following cases:
i. n < -25
ii. n > 25
iii. n = 0
Q4. Consider the STDTFT defined as
$ X(\omega ,n)=\sum_k x[k]w[n-k]e^{-j\omega k} $
where x[n] is the speech signal and w[n] is the window sequence. Prove the following properties:
a. Linearity – if $ v[n]=ax[n]+by[n] $ ,then $ V(\omega ,n)=aX(\omega ,n)+bY(\omega, n) $.
b. Modulation – if $ v[n]=x[n]e^{j\omega_0n} $ ,then $ V(\omega ,n)=X(\omega -\omega_0,n) $.
Q5. Suppose we have two 4-pt sequences x[n] and h[n] described as follows:
$ \begin{align} x[n] &= cos(\frac{\pi n}{2})\text{ ,n=0,1,2,3} \\ h[n] &= 2^n\text{ ,n=0,1,2,3} \end{align} $
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