Jump to content

Circuit Theory/Convolution Integral/Examples/example49/Vc

From Wikibooks, open books for an open world
series LRC circuit ... find voltage across the resistor

Given that the source voltage is (2t-3t2), find voltage across the resistor.

This is the Vc solution.

Outline:

Transfer Function

[edit | edit source]
simplify((1/(s*0.25))/(4 + s + 1/(0.25*s)))

Homogeneous Solution

[edit | edit source]
solve(s^2 + 4.0*s + 4.0,s)

There are two equal roots at s = -2, so the solution has the form:

Particular Solution

[edit | edit source]

After a long time attached to a unit step function source, the inductor has shorted and the capacitor has opened. All the drop is across the capacitor. The current is zero.

This also means that C1 is still unknown.

Initial Conditions

[edit | edit source]

So far the full equation is:

At t = ∞ what is the B term's value?

limit(B*t*exp(-t),t = infinity)

Mupad says 0. So This means that at t = ∞:

Initial voltage across the capacitor is 0 so:

Initial current through the series leg is zero because of the assumed initial conditions of the inductor. This means i(0) = 0, so:

This means that i(t) =:

Impulse Solution

[edit | edit source]

Taking the derivative of the above get:

Convolution Integral

[edit | edit source]
f := (4*exp(-2*(t-x)) - 8*(t-x)exp(-2*(t-x)))*(2*x-3*x^2);
S :=int(f,x=0..t)

There will not be any constant since again, V_R(t) = 0 after a long time ... and the capacitor opens.