Laplace transforms: R series with RC parallel circuit: Difference between revisions
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Written by: Andrew Hellie |
Written by: Andrew Hellie |
||
Checked by: |
Checked by: Kendrick Mensink |
Revision as of 11:36, 29 October 2009
Problem Statement
- Find the Voltage across the capacitor for t>=0:
- Voltage across capacitor at t({0-})=0
Use Loop Equations to solve for the currents in and
- Loop 1 (Resistor Branch)
- ___________________________________equation (1)
- Loop 2 (Capacitor Branch)
- _______________________equation (2)
Solve equations (1) and (2) simultaneously
- Substituting equation (1) into equation (2) gives...
- simplifies to...
Take the Laplace Transform to move to the S-domain
Take the inverse Laplace transform to move back into the t-domain
- substitute this equation back into equation (1)
Voltage on Capacitor
Answer
- Volts
Apply the Initial and Final Value Theorems to find the initial and final values
- Initial Value Theorem
- Final Value Theorem
- Initial Value:
- Initial Value = 0 Volts
- Final Value:
- Final Value = 6 Volts
- Volts
- Volts
Bode Plot
- simplified to...
How to use break points and asymptotes to obtain the magnitude frequency response of the system...
The break points are the values of s in H(s) that make the numerator and or the denominator 0.
The location of the break points is the magnitude frequency response of the system.
Zeros are where the numerator is equal to zero.
Poles are when the denominator is equal to zero.
Use Convolution to find the output of the system
Written by: Andrew Hellie
Checked by: Kendrick Mensink