Answer:
(a) 2.8 V
(b) 5.6 V
(c) 9.8 V
Explanation:
Given:
Frequency of the generator (f) = 1300 Hz)
Terminal voltage (V) =12.0 V
Resistance of resistor (R) = 14.0 Ω
Capacitance of capacitor (C) = 4.40 μF = 4.40 × 10⁻⁶ F
Inductance of the inductor (L) = 6.00 mH = 6.00 × 10⁻³ H
In order to find the voltages across each, we first need to find the reactance and impedance.
Reactance of the inductor is given as:
[tex]X_L=2\pi f L\\\\X_L=2\times 3.14\times 1300\times 6.00\times 10^{-3}\\\\X_L=49\ \Omega[/tex]
Reactance of the capacitor is given as:
[tex]X_C=\frac{1}{2\pi fC}\\\\X_C=\frac{1}{2\times 3.14\times 1300\times 4.40\times 10^{-6}}\\\\X_C =28\ \Omega[/tex]
Now, impedance is given as:
[tex]Z=\sqrt{X_L^2+X_C^2}\\\\Z=\sqrt{(49)^2+(28)^2}\\\\Z=\sqrt{3185}=56.4\ \Omega[/tex]
Current across the circuit is given as:
[tex]I=\frac{V}{Z}\\\\I=\frac{12}{56.4}=0.2\ A[/tex]
As resistor, capacitor and inductor are connected in series, the current across each of them is same and equal to total current in the circuit.
(a)
Voltage across the resistor is given as:
[tex]V_R=IR\\\\V_R=0.2\times 14=2.8\ V[/tex]
Therefore, the voltage across resistor is 2.8 V.
(b)
Voltage across the capacitor is given as:
[tex]V_C=IX_C\\\\V_C=0.2\times 28=5.6\ V[/tex]
Therefore, the voltage across the capacitor is 5.6 V.
(c)
Voltage across the inductor is given as:
[tex]V_L=IX_L\\\\V_L=0.2\times 49=9.8\ V[/tex]
Therefore, the voltage across the inductor is 9.8 V.
