250+ TOP MCQs on Sinusoidal Response of an R-L Circuit and Answers

Network Theory Multiple Choice Questions on “Sinusoidal Response of an R-L Circuit”.

1. In the sinusoidal response of R-L circuit, the complementary function of the solution of i is?
A. i_c = ce^-t(R/L)
B. i_c = ce^t(RL)
C. i_c = ce^-t(RL)
D. i_c = ce^t(R/L)

Answer: A
Clarification: From the R-L circuit, we get the characteristic equation as (D+R/L)i=V/L cos⁡(ωt+θ). The complementary function of the solution i is i_c = ce^-t(R/L).

2. The particular current obtained from the solution of i in the sinusoidal response of R-L circuit is?
A. i_p = V/√(R²+(ωL)²) cos⁡(ωt+θ+tan^-1(ωL/R))
B. i_p = V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1(ωL/R))
C. i_p = V/√(R²+(ωL)²) cos⁡(ωt-θ+tan^-1(ωL/R))
D. i_p = V/√(R²+(ωL)²) cos⁡(ωt-θ+tan^-1(ωL/R))

Answer: B
Clarification: The characteristic equation consists of two parts, viz. complementary function and particular integral. The particular integral is i_p = V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1(ωL/R)).

3. The value of ‘c’ in complementary function of ‘i’ is?
A. c = -V/√(R²+(ωL)²) cos⁡(θ+tan^-1(ωL/R))
B. c = -V/√(R²+(ωL)²) cos⁡(θ-tan^-1(ωL/R))
C. c = V/√(R²+(ωL)²) cos⁡(θ+tan^-1(ωL/R))
D. c = V/√(R²+(ωL)²) cos⁡(θ-tan^-1(ωL/R))

Answer: B
Clarification: Since the inductor does not allow sudden changes in currents, at t = 0, i = 0. So, c = -V/√(R²+(ωL)²) cos⁡(θ-tan^-1(ωL/R)).

4. The complete solution of the current in the sinusoidal response of R-L circuit is?
A. i = e^-t(R/L)[V/√(R²+(ωL)²) cos⁡(θ-tan^-1)⁡(ωL/R))]+V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1)⁡(ωL/R))
B. i = e^-t(R/L)[-V/√(R²+(ωL)²) cos⁡(θ-tan^-1)(ωL/R))]-V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1)⁡(ωL/R))
C. i = e^-t(R/L)[V/√(R²+(ωL)²) cos⁡(θ-tan^-1)⁡(ωL/R))]-V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1)⁡(ωL/R))
D. i = e^-t(R/L)[-V/√(R²+(ωL)²) cos⁡(θ-tan^-1)⁡(ωL/R))]+V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1)⁡(ωL/R))

Answer: D
Clarification: The complete solution for the current becomes i = e^-t(R/L)[-V/√(R²+(ωL)²) cos⁡(θ-tan^-1)⁡(ωL/R))]+V/√(R²+(ωL)²)cos⁡(ωt+θ-tan^-1)⁡(ωL/R)).

5. In the circuit shown below, the switch is closed at t = 0, applied voltage is v (t) = 100cos (103t+π/2), resistance R = 20Ω and inductance L = 0.1H. The complementary function of the solution of ‘i’ is?

A. i_c = ce^-100t
B. i_c = ce^100t
C. i_c = ce^-200t
D. i_c = ce^200t

Answer: C
Clarification: By applying Kirchhoff’s voltage law to the circuit, we have 20i+0.1di/dt=100cos⁡(10³ t+π/2) => (D+200)i=1000cos⁡(1000t+π/2). The complementary function is i_c = ce^-200t.

6. In the circuit shown below, the switch is closed at t = 0, applied voltage is v (t) = 100cos (103t+π/2), resistance R = 20Ω and inductance L = 0.1H. The particular integral of the solution of ‘i_p’ is?

A. i_p = 0.98cos⁡(1000t+π/2-78.6^o)
B. i_p = 0.98cos⁡(1000t-π/2-78.6^o)
C. i_p = 0.98cos⁡(1000t-π/2+78.6^o)
D. i_p = 0.98cos⁡(1000t+π/2+78.6^o)

Answer: A
Clarification: Assuming particular integral as i_p = A cos (ωt + θ) + B sin(ωt + θ). We get i_p = V/√(R²+(ωL)²) cos⁡(ωt+θ-tan^-1(ωL/R)) where ω = 1000 rad/sec, V = 100V, θ = π/2, L = 0.1H, R = 20Ω. On substituting, we get i_p = 0.98cos⁡(1000t+π/2-78.6^o).

7. In the circuit shown below, the switch is closed at t = 0, applied voltage is v (t) = 100cos (103t+π/2), resistance R = 20Ω and inductance L = 0.1H. The complete solution of ‘i’ is?

A. i = ce^-200t + 0.98cos⁡(1000t-π/2-78.6^o)
B. i = ce^-200t + 0.98cos⁡(1000t+π/2-78.6^o)
C. i = ce^-200t + 0.98cos⁡(1000t+π/2+78.6^o)
D. i = ce^-200t + 0.98cos⁡(1000t-π/2+78.6^o)

Answer: B
Clarification: The complete solution for the current is the sum of the complementary function and the particular integral. The complete solution for the current becomes i = ce^-200t + 0.98cos⁡(1000t+π/2-78.6^o).

8. The current flowing through the circuit at t = 0 in the circuit shown below is?

A. 1
B. 2
C. 3
D. 0

Answer: D
Clarification: At t = 0 that is initially the current flowing through the circuit is zero that is i = 0. So, i = 0.

9. In the circuit shown below, the switch is closed at t = 0, applied voltage is v (t) = 100cos (103t+π/2), resistance R = 20Ω and inductance L = 0.1H. The value of c in the complementary function of ‘i’ is?

A. c = -0.98cos⁡(π/2-78.6^o)
B. c = -0.98cos⁡(π/2+78.6^o)
C. c = 0.98cos⁡(π/2+78.6^o)
D. c = 0.98cos⁡(π/2-78.6^o)

Answer: A
Clarification: At t = 0, the current flowing through the circuit is zero. Placing i = 0 in the current equation we get c = -0.98cos⁡(π/2-78.6^o).

10. In the circuit shown below, the switch is closed at t = 0, applied voltage is v (t) = 100cos (103t+π/2), resistance R = 20Ω and inductance L = 0.1H. The complete solution of ‘i’ is?

A. i = [-0.98 cos⁡(π/2-78.6^o)] exp⁡(-200t)+0.98cos⁡(1000t+π/2-78.6^o)
B. i = [-0.98 cos⁡(π/2-78.6^o)] exp⁡(-200t)-0.98cos⁡(1000t+π/2-78.6^o)
C. i = [0.98 cos⁡(π/2-78.6^o)] exp⁡(-200t)-0.98cos⁡(1000t+π/2-78.6^o)
D. i = [0.98 cos⁡(π/2-78.6^o)] exp⁡(-200t)+0.98cos⁡(1000t+π/2-78.6^o)

Answer: A
Clarification: The complete solution for the current is the sum of the complementary function and the particular integral.
So, i = [-0.98 cos⁡(π/2-78.6^o)] exp⁡(-200t)+0.98cos⁡(1000t+π/2-78.6^o).