- #1
Saladsamurai
- 3,020
- 7
Homework Statement
I just want to verify that I am dong this correctly and if not, where my misconceptions are. I keep getting a different answer so I am going to go through this step by step:
After a some steps in a controls problem, I end up with a function in the Laplace domain:
[tex]\Theta(s) = \frac{12}{\frac{6}{5}s^2 +96}\qquad(1)[/tex]
Homework Equations
From table, I know that
[tex]\mathcal L[Be^{-at}\sin(\omega t)]=\frac{B\omega}{(s+a)^2 + \omega^2}\qquad(2)[/tex]
The Attempt at a Solution
So the idea is to make my equation (1) take the form of the known equation (2):
First, I factored the denominator so that s2 has a coefficient of 1:
[tex]\frac{12}{\frac{6}{5}s^2 +96}=\frac{1}{\frac{6}{5}}\cdot \frac{12}{s^2+80}[/tex]
Comparing the denominators of each we have:
[tex](s+a)^2 + \omega^2 = s^2 +80[/tex]
[tex]\Rightarrow s^2 + 2as + a^2 + \omega^2 =s^2 +80[/tex]
[tex]\therefore a = 0 \qquad\qquad \omega^2 = 80[/tex]
So we now have to compare the numerators:
[tex]12 = B*\omega[/tex]
[tex]\Rightarrow B = \frac{12}{\omega}[/tex]
[tex]\Rightarrow B=\frac{12}{\sqrt{80}}[/tex]
Thus, we can write:
[tex]\Theta(s) =\frac{5}{6}\cdot\frac{(\frac{12}{\sqrt{80}})*\sqrt{80}}{(s+0)^2+ \sqrt{80}^2}[/tex]
So, in the time domain, we have:
[tex]\mathcal L^{-1} [\Theta(s)]=\theta(t) = \frac{10}{\sqrt{80}}\cdot\sin(\sqrt{80}t)[/tex]
or
[tex]\frac{\sqrt{5}}{2}\sin(4\sqrt5 t)[/tex]
I have gotten this result a couple of times, so I think I am correct, but my friend got something a little different.
Are there any blatant errors I am making?
Thanks!