For the circuit shown below, determine: a) Amplitude of the Voltage Source b) RMS value of the Voltage Source c) Frequency of the Voltage Source d) Phase Angle of the Voltage Source e) Total Resistance f) Total Inductance g) Total Capacitance h) Inductive Reactance i) Capacitive Reactance j) Total Impedance in Polar Form k) Total Current in Polar Form I) Voltage across the Resistor m) Voltage across the Inductance n) Voltage across the Capacitor o) Draw all voltages and current on the Complex Plane e = √2(20) sin 3771 + R₁ = 6 R₂ = 40 L₁ = 0.05 H L₂ = 0.05 H www moo voo + UR ₁01) C₁ = 200 μF C₂ = 200 μF + UL HE + UC

 

For the circuit shown below, determine:

1. Amplitude of the Voltage Source
2. RMS value of the Voltage Source
3. Frequency of the Voltage Source
4. Phase Angle of the Voltage Source
5. Total Resistance
6. Total Inductance
7. Total Capacitance
8. Inductive Reactance
9. Capacitive Reactance
10. Total Impedance in Polar Form
11. Total Current in Polar Form
12. Voltage across the Resistor
13. Voltage across the Inductance
14. Voltage across the Capacitor
15. Draw all voltages and current on the Complex Plane

 

show all the work

 

Transcribed Image Text:

For the circuit shown below, determine: a) Amplitude of the Voltage Source b) RMS value of the Voltage Source c) Frequency of the Voltage Source d) Phase Angle of the Voltage Source e) Total Resistance f) Total Inductance g) Total Capacitance h) i) j) Total Impedance in Polar Form k) Total Current in Polar Form I) Voltage across the Resistor m) Voltage across the Inductance n) Voltage across the Capacitor o) Draw all voltages and current on the Complex Plane Inductive Reactance Capacitive Reactance e = √2(20) sin 377t + ol R₁ + = 6Ω R2 = 4Ω L UR = 0.05 H moo + 42 UL C₁ = 200 μF C₂ = 0.05 H voo + UC = 200 μF HE