Frequency Domain Analysis - the math

AI Thread Summary
The discussion focuses on understanding the derivation of the constant 'a' in Frequency Domain Analysis from Ogata's Control Theory. The value of 'a' is given as a = G(s)(ωX)/(s² + ω²), and participants clarify that this is obtained by evaluating limits as s approaches -jω and jω. The substitution of s = -jω is explained as a mathematical method to derive coefficients needed for analysis. Some contributors suggest that instead of limits, one could factor the denominator into complex factors to find the inverse Laplace transform. The conversation emphasizes the importance of these techniques in control theory analysis.
phiby
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I am studying Control Theory from Ogata. My math is a little rusty, so this is a math question about Frequency Domain Analysis.

Check this page - http://www.flickr.com/photos/66943862@N06/6337116280/sizes/l/in/photostream/

I get everything upto Equation 8-4

However I don't get the line after that.

The line "where the constant a can be evaluated from Equation (8-2) as follows"

And they write the value of a.

How is
a = G(s) (ωX) /(s^2 + ω^2).

How do they arrive at this value of a?

Can someone help?

And why did they substitute s = -jω after that?
 
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here is another way

http://img41.imageshack.us/content_round.php?page=done&l=img41/4643/12112011130.jpg

i put s = - jw to get value of a, if you put s = jw you will get the value of a bar
 
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reddvoid said:
here is another way

http://img41.imageshack.us/content_round.php?page=done&l=img41/4643/12112011130.jpg

i put s = - jw to get value of a, if you put s = jw you will get the value of a bar

Thank you. That's a little clearer.

You get values of a & abar by evaluating the limit as s = -jω & s = jω

However, I still don't get why you evaluate these limits?
 
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Its simply a mathematical way of obtaining the coefficients. You can simply factorize the denominator into complex factors and proceed to obtain the inverse laplace transform.
 

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