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From <math>a_k=\frac{sin(k * w_o * T_1)}{(k*\pi)}</math>,
 
From <math>a_k=\frac{sin(k * w_o * T_1)}{(k*\pi)}</math>,
  
3) a<sub>k</sub> = <math>\frac{sin(k\\frac{pi}{2})}{(k\pi)}</math>([[User:Clarkjv|Clarkjv]] 18:25, 8 February 2011 (UTC))
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3) a<sub>k</sub> = <math>\frac{sin(k\pi/2)}{(k\pi)}</math>
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([[User:Clarkjv|Clarkjv]] 18:25, 8 February 2011 (UTC))
  
 
[[Category:ECE301Spring2011Boutin]] [[Category:Problem_solving]]
 
[[Category:ECE301Spring2011Boutin]] [[Category:Problem_solving]]

Revision as of 13:46, 8 February 2011

Practice Question on Computing the Fourier Series discrete-time signal

Obtain the Fourier series the DT signal

$ x[n] = \left\{ \begin{array}{ll} 1, & \text{ for } -5\leq n \leq 5,\\ 0, & \text{ for } 5< |n| \leq 10. \end{array} \right. \ $

x[n] periodic with period 20.


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Answer 1

Solution 1:

1) ωo = $ \frac{2\pi}{T} = 2\frac{\pi}{20}=\frac{\pi}{10} $

2) ao is the DC value of the AC signal and is therefore 1/2

3) ak = $ 1/20 * \int_a^b \! x(t)*e^{-j*k*(\pi/10)*t}\,dx $ = $ e^{j*k*\pi/2}-e^{-j*k*\pi/2}/(2*\pi*j*k) = \frac{sin(k\pi/2)}{(k\pi)} $(Clarkjv 18:25, 8 February 2011 (UTC))

Solution 2:

1)ωo=$ \frac{\pi}{10} $ (see solution 1)

From example 3.5 (sec. 3.3 pg 193 Signals and Systems 2nd edition Oppenheim)

$ a_k=\frac{sin(k * w_o * T_1)}{(k*\pi)} $,

2)ao is still the DC value of the AC signal and therefore, ao = 1/2

From $ a_k=\frac{sin(k * w_o * T_1)}{(k*\pi)} $,

3) ak = $ \frac{sin(k\pi/2)}{(k\pi)} $ (Clarkjv 18:25, 8 February 2011 (UTC))

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