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which is our answer. |
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which is our answer. |
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===Initial/Final Value Theorems=== |
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We now want to use the Initial and Final Value Theorems on this problem. |
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The Initial Value Theorem states that |
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<math>\lim_{s \to \infty}sF(s)=f(0^+)</math> |
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<math> \Rightarrow \lim_{s \to \infty}\dfrac{s^3}{(s^2+400)(0.01s^2+s+10000)}=i(0) </math> |
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<math> \Rightarrow i(0)=0 </math> |
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In addition, when we actually evaluate <math>i(0)</math> from our equation for <math>i(t)</math>, we find it to be 0 as well. So, things check out there. |
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The Final Value Theorem states that |
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<math> \lim_{s \to 0}sF(s)=f(\infty)</math> |
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<math> \Rightarrow \lim_{s \to 0}\dfrac{s^3}{(s^2+400)(0.01s^2+s+10000)}=i(\infty) </math> |
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<math> \Rightarrow i(\infty)=0</math> |
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This time, when we actually evaluate ''i''(∞) from the equation for <math>i(t)</math>, we find it to be undefined. So here, the Final Value Theorem tells us something that is not necessarily true (in fact, because we have oscillating functions, we know that ''i''(∞) will not be zero). |
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Laplace Transform Example: Series RLC Circuit
Problem
Given a series RLC circuit with , , and , having power source , find an expression for if and .
Solution
We begin with the general formula for voltage drops around the circuit:
Substituting numbers, we get
Now, we take the Laplace Transform and get
Using the fact that , we get
Using partial fraction decomposition, we find that
Finally, we take the inverse Laplace transform to obtain
which is our answer.
Initial/Final Value Theorems
We now want to use the Initial and Final Value Theorems on this problem.
The Initial Value Theorem states that
In addition, when we actually evaluate from our equation for , we find it to be 0 as well. So, things check out there.
The Final Value Theorem states that
This time, when we actually evaluate i(∞) from the equation for , we find it to be undefined. So here, the Final Value Theorem tells us something that is not necessarily true (in fact, because we have oscillating functions, we know that i(∞) will not be zero).
Written by Nathan Reeves ~ Checked by