Practice Problems
Resistors and Capacitors
Directions:
On this worksheet you will review the formulas and relationships for capacitors wired in series and in parallel and well as capacitors in DC circuits.
omit
Question 1
In the circuit shown below, the values for each capacitor are:
C
1
= 6 µF C
2
= 3 µF C
3
= 11 µF;
Based on these values, what would be the total capacitance of this combination?
This diagram is only referenced in Questions 1-4.
1.7 µF
4.20 µF
20.0 µF
8.36 µF
omit
Question 2
What is the charge on each plate of capacitor C
1
if the emf of the battery is 14 volts?
58.8 µC
84.0 µC
19.6 µC
3.33 µC
omit
Question 3
What is the voltage drop across capacitor C
3
?
4.7 volts
9.8 volts
4.2 volts
4.9 volts
omit
Question 4
What is the charge on capacitor C
2
?
4.67 µC
46.2 µC
12.6 µC
19.6 µC
omit
Question 5
What would be the capacitance of a parallel plate capacitor where each plate has an area of 49 cm
2
and the plates are separated by 4 mm?
1.73 x 10
-9
F
7.22 x 10
-12
F
1.08 x 10
-11
F
5.42 x 10
-11
F
omit
Question 6
If the capacitor in Question #5 were to be charged by a 14-V battery, how much energy would be stored in the electric field between the capacitor's plates?
1.06 x 10
-9
Joules
7.08 x 10
-10
Joules
1.52 x 10
-10
Joules
5.31 x 10
-9
Joules
omit
Question 7
In the circuit shown below, R
1
has a resistance of 300 ohms, R
2
has a resistance of 1100 ohms, and the battery has an emf of 14 volts. What would be the voltage lost across R
1
when steady state currents have been achieved?
7.00 volts
3.82 volts
14.0 volts
3.00 volts
omit
Question 8
If the capacitor has a capacitance equal to 6 µF, how muc charge would be stored on its plates when steady-state conditions have been reached?
18.0 µC
the charge cannot be determined
84.0 µC
66.0 µC
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