Difference between revisions of "FM Homework Assignment Questions"

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(Questions and Answers (Q&A))
(Questions and Answers (Q&A))
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'''Question 2:'''  <insert here>
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'''Question 2:'''  Is the equation for the reference signal at the top of page 3 of the assignment? (v(t) = ...) I'm trying to integrate to get phi(t) but the integral of the message signal is always zero.
 +
 
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>> syms t;
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>> sin_m_of_t = sin(2*pi*2000*t);
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>> int(sin_m_of_t, 0, 277775)
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ans = 0
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so that implies that for the sinusoidal input v(t) = A + n_c(t) + j*n_s(t)? It is just a sine wave though, so I suppose it does make sense that its integral over a whole number multiples of 2*pi is zero.
 +
Also, is my upper limit on the integral correct? ( = delta * (number of samples - 1))
 +
 
 
:'''Answer 2:'''  <blah blah>
 
:'''Answer 2:'''  <blah blah>
  

Revision as of 23:03, 11 April 2008

Introduction

Please feel free to use this page like a message board to ask any questions you like about the FM homework assignment.


Questions and Answers (Q&A)

Question 1: I have been trying for days, using the bilinear transform (matlab: bilinear) to convert the filters from continuous time domain to discrete time domain. For the butterworth filter, I even used the butterworth function provided by matlab (matlab: butter). Nothing worked, the frequency responses always showed a difference of about a factor of 10. I then stumbled across another discretisation method from the Control Systems Toolbox: c2d. For the first two filters, I simply used a bilinear tustin approximation ( Hn = c2d(Hn_a,ts,'tustin') ) and for the third filter, I used the bilinear tustin approximation with prewarping, as with higher frequencies, the prewarping effect is more visible ( H3=c2d(H3_a,ts,'prewarp',omega_c3) ) The approximation using a zero order hold also works, but the prewarp is more accurate. My question now: Is it mandatory that we use the bilinear() function, or is the above described method okay?

Answer 1: <blah blah>


Question 2: Is the equation for the reference signal at the top of page 3 of the assignment? (v(t) = ...) I'm trying to integrate to get phi(t) but the integral of the message signal is always zero.

>> syms t; >> sin_m_of_t = sin(2*pi*2000*t); >> int(sin_m_of_t, 0, 277775)

ans = 0

so that implies that for the sinusoidal input v(t) = A + n_c(t) + j*n_s(t)? It is just a sine wave though, so I suppose it does make sense that its integral over a whole number multiples of 2*pi is zero. Also, is my upper limit on the integral correct? ( = delta * (number of samples - 1))

Answer 2: <blah blah>


Question 3: <insert here>

Answer 3: <blah blah>

See Also

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