300+ REAL TIME Network Theory Objective Questions & Answers 2023

250+ TOP MCQs on Nodal Analysis and Answers

Network Theory Multiple Choice Questions on “Nodal Analysis”.

1. If there are 8 nodes in network, we can get ____ number of equations in the nodal analysis.
A. 9
B. 8
C. 7
D. 6

Answer: C
Clarification: Number of equations = N-1 = 7. So as there are 8 nodes in network, we can get 7 number of equations in the nodal analysis.

2. Nodal analysis can be applied for non planar networks also.
A. true
B. false

Answer: A
Clarification: Nodal analysis is applicable for both planar and non planar networks. Each node in a circuit can be assigned a number or a letter.

3. In nodal analysis how many nodes are taken as reference nodes?
A. 1
B. 2
C. 3
D. 4

Answer: A
Clarification: In nodal analysis only one node is taken as reference node. And the node voltage is the voltage of a given node with respect to one particular node called the reference node.

4. Find the voltage at node P in the following figure.

A. 8V
B. 9V
C. 10V
D. 11V

Answer: B
Clarification: I₁ = (4-V)/2, I₂ = (V+6)/3. The nodal equation at node P will be I₁+3=I₂. On solving, V=9V.

5. Find the resistor value R₁(Ω) in the figure shown below.

A. 10
B. 11
C. 12
D. 13

Answer: C
Clarification: 10=(V₁-V₂)/14+(V₁-V₃)/R₁. From the circuit, V₁=100V, V₂=15×2=30V, V₃=40V. On solving, R₁=12Ω.

6. Find the value of the resistor R₂ (Ω) in the circuit shown below.

A. 5
B. 6
C. 7
D. 8

Answer: B
Clarification: As V₁=100V, V₂=15×2=30V, V₃=40V. (V₁-V₂)/14+(V₁-V₃)/R₂=15. On solving we get R₂ = 6Ω.

7. Find the voltage (V) at node 1 in the circuit shown.

A. 5.32
B. 6.32
C. 7.32
D. 8.32

Answer: B
Clarification: At node 1, (1/1+1/2+1/3)V₁-(1/3)V₂ = 10/1. At node 2, -(1/3)V₁+(1/3+1/6+1/5)V₂ = 2/5+5/6. On solving above equations, we get V₁=6.32V.

8. Find the voltage (V) at node 2 in the circuit shown below.

A. 2.7
B. 3.7
C. 4.7
D. 5.7

Answer: C
Clarification: At node 1, (1/1+1/2+1/3)V₁-(1/3)V₂ = 10/1. At node 2, -(1/3)V₁+(1/3+1/6+1/5)V₂ = 2/5+5/6. On solving above equations, we get V₂=4.7V.

9. Find the voltage at node 1 of the circuit shown below.

A. 32.7
B. 33.7
C. 34.7
D. 35.7

Answer: B
Clarification: Applying Kirchhoff’s current law at node 1, 10 = V₁/10+(V₁-V₂)/3. At node 2, (V₂-V₁)/3+V₂/5+(V₂-10)/1=0. On solving the above equations, we get V₁=33.7V.

10. Find the voltage at node 2 of the circuit shown below.

A. 13
B. 14
C. 15
D. 16

Answer: B
Clarification: Applying Kirchhoff’s current law at node 1, 10 = V₁/10+(V₁-V₂)/3. At node 2, (V₂-V₁)/3+V₂/5+(V₂-10)/1=0. On solving the above equations, we get V₂=14V.

250+ TOP MCQs on Advanced Problems on Network Theorems – 2 and Answers

Advanced Network Theory Questions on “Advanced Problems on Network Theorems – 2”.

1. A network contains linear resistors and ideal voltage source s. If values of all the resistors are doubled, then voltage across each resistor is __________
A. Halved
B. Doubled
C. Increases by 2 times
D. Remains same

Answer: D
Clarification: V / R ratio is a constant R. If R is doubled then, electric current will become half. So voltage across each resistor is same.

2. A voltage waveform V(t) = 12t² is applied across a 1 H inductor for t ≥ 0, with initial electric current through it being zero. The electric current through the inductor for t ≥ 0 is given by __________
A. 12 t
B. 24 t
C. 12 t³
D. 4 t³

Answer: D
Clarification: We know that, I = (frac{1}{L} int_0^t V ,dt)
= 1(int_0^t 12 t^2 ,dt)
= 4 t³.

3. The linear circuit element among the following is ___________
A. Capacitor
B. Inductor
C. Resistor
D. Capacitor & Inductor

Answer: C
Clarification: A linear circuit element does not change its value with voltage or current. The resistance is only one among the others does not change its value with voltage or current.

4. In the circuit shown, V_C is zero at t=0 s. For t>0, the capacitor current I_C(t), where t is in second, is ___________

A. 0.50 e^-25t mA
B. 0.25 e^-25t mA
C. 0.50 e^-12.5t mA
D. 0.25 e^-6.25t mA

Answer: A
Clarification: The capacitor voltage V_C (t) = V_C (∞) – [V_C (∞)-V_C (0)]e^-t/RC
R = 20 || 20 = (frac{20×20}{20+20} = frac{400}{40}) = 10 kΩ
V_C (∞) = 10 × (frac{20}{20+20}) = 5 V
Given, V_C (0) = 0
∴ V_C (t) = 5 – (5-0)e^{-t/10×4×10^(-6)×10^3}
= 5(1 – e^-25t)
I_C (t) = C(frac{dV_C (t)}{dt} = 4×10^{-6} frac{d}{dt}5(1-e^{-25t}))
= 4 × 10^-6 × 5 × 25e^-25t
∴ I_L (t) = 0.50e^-2.5t mA.

5. In the circuit given below, the phasor voltage V_AB (in volt) is _________

A. Zero
B. 5∠30°
C. 12.5∠30°
D. 17∠30°

Answer: D
Clarification: Equivalent impedance = (5 + j3) || (5 – √3)
= (frac{(5+j3)×(5 – sqrt{3})}{(5+j3) + (5 – sqrt{3})} )
= (frac{25+9}{10}) = 3.4 Ω
V_AB = Current × Impedance
= 5∠30° × 3.4
= 17∠30°.

6. For the circuit given below, the driving point impedance is given by, Z(s) = (frac{0.2s}{s^2+0.1s+2} ). The component values are _________

A. L = 5 H, R = 0.5 Ω, C = 0.1 F
B. L = 0.1 H, R = 0.5 Ω, C = 5 F
C. L = 5 H, R = 2 Ω, C = 0.1 F
D. L = 0.1 H, R = 2 Ω, C = 5 F

Answer: D
Clarification: Dividing point impedance = R || sL || (frac{1}{sC} )
= (Big{frac{(R)(frac{1}{sC})}{R + frac{1}{sC}}Big}) || sL
= (frac{frac{R}{1+sRC}}{frac{R}{1+sRC}+sL} )
= (frac{sRL}{s^2 RLC+sL+R} )
Given that, Z(s) = (frac{0.2s}{s^2+0.1s+2} )
∴ On comparing, we get L = 0.1 H, R = 2 Ω, C = 5 F.

7. What is the power loss in the 10 Ω resistor in the network shown in the figure below?

A. 15.13 W
B. 11.23 W
C. 16 W
D. 14 W

Answer: A
Clarification: In mesh aef, 8(I₁ – I₃) + 3(I₁ – I₂) = 15
Or, 11 I₁ – 3 I₂ – 8I₃ = 15
In mesh efd, 5(I₂ – I₃) + 2I₂ + 3(I₂ – I₁) = 0
Or, -3 I₁ + 10I₂ – 5I₃ = 0
In mesh abcde, 10I₃ + 5(I₃ – I₂) + 8(I₃ – I₁) = 0
Or, -8I₁ – 5I₂ +23I₃ = 0
Thus loop equations are,
11 I₁ – 3 I₂ – 8I₃ = 15
-3 I₁ + 10I₂ – 5I₃ = 0
-8I₁ – 5I₂ + 23I₃ = 0
Solving by Cramer’s rule, I₃ = current through the 10Ω resistor = 1.23 A
∴ Current through 10 Ω resistor = 1.23 A
Power loss (P) = (I_3^2 r) = (1.23)²×10 = 15.13 W.

8. The switch S is the circuit shown in the figure is ideal. If the switch is repeatedly closed for 1 ms and opened for 1 ms, the average value of i(t) is ____________

A. 0.25 mA
B. 0.35 mA
C. 0.5 mA
D. 1 mA

Answer: A
Clarification: Since i = (frac{5}{10 × 10^{-3}}) = 0.5 × 10³ = 0.5 mA
As the switch is repeatedly close, then i(t) will be a square wave.
So average value of electric current is ((frac{0.5}{2})) = 0.25 mA.

9. In the circuit given below the value of resistance, R_eq is ___________

A. 10 Ω
B. 11.86 Ω
C. 11.18 Ω
D. 25 Ω

Answer: C
Clarification: The circuit is as shown in figure below.

R_eq = 5 + (frac{10(R_{eq}+5)}{10 + 5 + R_{eq}})
Or, (R_{eq}^2 + 15R_{eq}) = 5R_eq + 75 + 10R_eq + 50
Or, R_eq = (sqrt{125}) = 11.18 Ω.

10. A particular electric current is made up of two component: a 10 A and a sine wave of peak value 14.14 A. The average value of electric current is __________
A. 0
B. 24.14 A
C. 10 A
D. 14.14 A

Answer: C
Clarification: Average dc electric current = 10 A
Average ac electric current = 0 A as it is alternating in nature.
Average electric current = 10 + 0 = 10 A.

11. Given that, R₁ = 36 Ω and R₂ = 75 Ω, each having tolerance of ±5% are connected in series. The value of resultant resistance is ___________
A. 111 ± 0 Ω
B. 111 ± 2.77 Ω
C. 111 ± 5.55 Ω
D. 111 ± 7.23 Ω

Answer: C
Clarification: R₁ = 36 ± 5% = 36 ± 1.8 Ω
R₂ = 75 ± 5% = 75 ± 3.75 Ω
∴ R₁ + R₂ = 111 ± 5.55 Ω.

12. In the circuit of figure below a charge of 600 C is delivered to 100 V source in a 1 minute. The value of V₁ is ___________

A. 30 V
B. 60 V
C. 120 V
D. 240 V

Answer: D
Clarification: In order for 600 C charges to be delivered to 100 V source, the electric current must be anti-clockwise.
(i = frac{dQ}{dt} = frac{600}{60}) = 10A
Applying KVL we get
V₁ + 60 – 100 = 10 × 20 ⇒ V₁ = 240 V.

13. The energy required to charge a 10 μF capacitor to 100 V is ____________
A. 0.01 J
B. 0.05 J
C. 5 X 10^-9 J
D. 10 X 10^-9 J

Answer: B
Clarification: E = (frac{1}{2} CV^2)
= 5 X 10^-6 X 100²
= 0.05 J.

14. Among the following, the active element of electrical circuit is ____________
A. Voltage source
B. Current source
C. Resistance
D. Voltage and current source both

Answer: D
Clarification: We know that active elements are the ones that are used to drive the circuit. They also cause the electric current to flow through the circuit or the voltage drop across the element. Here only the voltage and current source are the ones satisfying the above conditions.

15. In the circuit given below, the source current is _________

A. 2 A
B. 3 A
C. 0.54 A
D. 1.5 A

Answer: C
Clarification: In the given figure, R_X = R_Y = R_Z = (frac{5×5}{5+5+5}) = 1.67 Ω
Here, R = [(R_X + 2) || (R_Y + 3)] + R_X
= (3.67 || 4.67) + R_Z
= (frac{3.67 × 4.67}{3.67 + 4.67}) + 1.67
= (frac{17.1389}{8.34}) + 1.67
= 3.725 Ω
∴ I = (frac{V}{R} = frac{2}{3.725}) = 0.54 A.

250+ TOP MCQs on Problems of Series Resonance Involving Frequency Response of Series Resonant Circuit and Answers

Network Theory Questions & Answers for Exams on “Problems of Series Resonance Involving Frequency Response of Series Resonant Circuit”.

1. A series RLC circuit has R = 50 Ω, L = 0.01 H and C = 0.04 × 10^-6 F. System voltage is 100 V. The frequency, at which the maximum voltage appears across the capacitor, is?
A. 5937.81 Hz
B. 7370 Hz
C. 7937.81 Hz
D. 981 Hz

Answer: C
Clarification: Frequency f_c at which V_C is maximum f_c = (frac{1}{2π}Big[frac{1}{0.01×0.01×10^{-6}} – frac{50×50}{2×0.01×0.01}Big]^{0.5})
So, f_c = 7937.81 Hz.

2. A series RLC circuit has R = 50 Ω, L = 0.01 H and C = 0.04 × 10^-6 F. System voltage is 100 V. At this frequency, the circuit impedance is?
A. 50 – j2.5 Ω
B. 50 – j2.8 Ω
C. 50 + j2.5 Ω
D. 50 + j2.8 Ω

Answer: A
Clarification: Z = R + j (ωL + (frac{1}{ωC})) = 50 + j (left(2π × 7937.81 × 0.01 – frac{1}{2π×7937.81×0.04×10^{-6}}right)) = 50 – j2.5 Ω.

3. Given, R = 10 Ω, L = 100 mH and C = 10 μF. The values of ω₀, ω₁ and ω₂ respectively are?

A. ω₀ = 1000 rad/s, ω₁ = 951.25 rad/s, ω₂ = 1075.54 rad/s
B. ω₀ = 1000 rad/s, ω₁ = 975.25 rad/s, ω₂ = 1051.25 rad/s
C. ω₀ = 1000 rad/s, ω₁ = 951.25 rad/s, ω₂ = 1051.25 rad/s
D. ω₀ = 1000 rad/s, ω₁ = 825.30 rad/s, ω₂ = 1075.54 rad/s

Answer: C
Clarification: ω₀ = (frac{1}{sqrt{100×10^{-3}×10×10^{-6}}}) = 1000 rad/s
Now, ω₁ = (frac{-R + sqrt{R^2 + frac{4L}{C}}}{2L} = frac{-10 + frac{sqrt{100 + 4 × 100 × 10^{-3}}}{10×10^{-6}}}{2×100×10^{-3}}) = 951.25 rad/s
And, ω₂ = (frac{+R+ sqrt{R^2+ 4L/C}}{2L}) = 1051.25 rad/s.

4. Given, R = 10 Ω, L = 100 mH and C = 10 μF. Selectivity is?

A. 10
B. 1.2
C. 0.15
D. 0.1

Answer: D
Clarification: Selectivity = (frac{1}{Q})
Q = (frac{ωL}{R} = frac{1000×100×10^{-3}}{10})
∴ Q = 10
So, Selectivity = 0.1.

5. Two series resonant filters are shown below. Let the 3 dB bandwidth of filter 1 be B₁ and that of filter 2 be B₂. The value of (frac{B_1}{B_2}) is ____________

A. 0.25
B. 1
C. 0.5
D. 0.75

Answer: A
Clarification: For series resonant circuit, 3dB bandwidth is (frac{R}{L})
B₁ = (frac{R}{L_1})
B₂ = (frac{R}{L_2} = frac{4R}{L_1})
Hence, (frac{B_1}{B_2}) = 0.25.

6. A 440 V, 50 HZ AC source supplies a series LCR circuit with a capacitor and a coil. If the coil has 100 mΩ resistance and 15 mH inductance, then at a resonance frequency of 50 Hz, the half power frequencies of the circuit are?
A. 50.53 Hz, 49.57 Hz
B. 52.12 HZ, 49.8 Hz
C. 55.02 Hz, 48.95 Hz
D. 50 HZ, 49 Hz

Answer: A
Clarification: Bandwidth, BW = (frac{f_o}{Q} = frac{50}{47.115}) = 1.061 Hz
f₂, higher half power frequency = f₀ + (frac{BW}{2})
∴ f₂ = 50 + (frac{1.061}{2}) =50.53 Hz
f₁, lower half power frequency = f₀ – (frac{BW}{2})
∴ f₁ = 100 – (frac{1.59}{2}) = 49.47 Hz.

7. At what frequency will the current lead the voltage by 30° in a series circuit with R = 10Ω and C = 25 μF?
A. 11.4 kHz
B. 4.5 kHz
C. 1.1 kHz
D. 24.74 kHz

Answer: A
Clarification: From the impedance diagram, 10 – jX_C = Z∠-30°
∴ – X_C = 10 tan (-30°) = -5.77 Ω
∴ X_C = 5.77 Ω
Then, X_C = (frac{1}{2πfC}) or, f = (frac{1}{2πX_C C}) = 1103 HZ = 1.1 kHz.

8. A 440 V, 50 HZ AC source supplies a series LCR circuit with a capacitor and a coil. If the coil has 100 mΩ resistance and 15 mH inductance, then at a resonance frequency of 50 Hz, what is the value of the capacitor?
A. 676 μF
B. 575 μF
C. 591 μF
D. 610 μF

Answer: A
Clarification: We know that f_o = (frac{1}{2πsqrt{LC}})
Or, 50 = (frac{1}{2πsqrt{5×10^{-3}×C}})
Or, C = (frac{1}{4π^2×50^2×15×10^{-3}}) ≈ 676 μF.

9. A 440 V, 50 HZ AC source supplies a series LCR circuit with a capacitor and a coil. If the coil has 100 mΩ resistance and 15 mH inductance, then at a resonance frequency of 50 Hz, the Q factor of the circuit is?
A. 82.63
B. 47.115
C. 27.38
D. 92.38

Answer: B
Clarification: We know that, Q = (frac{ωL}{R})
Or, Q = (frac{2π×50×15×10^{-3}}{100×10^{-3}}) = 47.115.

10. For the circuit given below, if the frequency of the source is 50 Hz, then a value of t_o which results in a transient free response is?

A. 0
B. 1.78 ms
C. 7.23 ms
D. 9.21 ms

Answer: B
Clarification: For the ideal case, transient response will die out with time constant.
T = (frac{L}{R} = frac{0.01}{5}) = 0.002 s = 2 ms
Practically, T will be less than 2 ms.

11. In the circuit given below, the magnitudes of V_L and V_C are twice that of V_K. Calculate the inductance of the coil, given that f = 50.50 Hz.

A. 6.41 mH
B. 5.30 mH
C. 3.18 mH
D. 2.31 mH

Answer: C
Clarification: V_L = V_C = 2 VR
∴ Q = (frac{V_L}{V_R}) = 2
But we know, Q = (frac{ωL}{R} = frac{1}{ωCR})
∴ 2 = (frac{2πf × L}{5})
Or, L = 3.18 mH.

12. A circuit with a resistor, inductor and capacitor in series is resonant with frequency f Hz. If all the component values are now doubled, then the new resonant frequency will be?
A. 2 f
B. f
C. (frac{f}{4})
D. (frac{f}{2})

Answer: D
Clarification: Resonance frequency = (frac{1}{2πsqrt{LC}} = frac{1}{2π2sqrt{LC}})
Hence, (frac{f}{f_o} = frac{frac{1}{2πsqrt{LC}}}{frac{1}{2π2sqrt{LC}}}) = 2
∴ f = 2f_o.

13. A series RLC circuit has a resonance frequency of 1 kHz and a quality factor Q = 50. If R and L are doubled and C is kept same, the new Q of the circuit is?
A. 25.52
B. 35.35
C. 45.45
D. 20.02

Answer: B
Clarification: Quality factor Q of the series RLC circuit is given by, Q = (frac{1}{R} sqrt{frac{L}{C}})
Q_new = (frac{1}{2R} sqrt{frac{2L}{C}} = frac{1}{2} × frac{1}{R} sqrt{frac{2L}{C}} = frac{1}{2} × sqrt{2} × Q) = 35.35.

14. In a series RLC circuit R = 10 kΩ, L = 0.5 H and C = (frac{1}{250}) μF. Calculate the frequency when the circuit is in a state of resonance.
A. 4.089 × 10⁴ Hz
B. (frac{11111.1}{π})Hz
C. 4.089π × 10⁴ Hz
D. (frac{1}{π}) × 10⁴ Hz

Answer: B
Clarification: Resonance frequency = (frac{1}{2πsqrt{LC}})
= (frac{1}{2πsqrt{frac{1}{250} × 10^{-6} × 0.5}} = frac{11111.1}{π})Hz.

15. In a series RLC circuit for lower frequency and for higher frequency, power factors are respectively ______________
A. Leading, Lagging
B. Lagging, Leading
C. Independent of Frequency
D. Same in both cases

Answer: A
Clarification: A Leading power factor means that the current in the circuit leads the applied voltage. This condition occurs in capacitive circuits. On the other hand, a lagging power factor indicates that the current lags the voltage and this condition happens in an inductive circuit.

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

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

1. The expression of current in R-L circuit is?
A. i=(V/R)(1+exp⁡((R/L)t))
B. i=-(V/R)(1-exp⁡((R/L)t))
C. i=-(V/R)(1+exp⁡((R/L)t))
D. i=(V/R)(1-exp⁡((R/L)t))

Answer: D
Clarification: The expression of current in R-L circuit is i = (V/R)-(V/R)exp⁡((R/L)t). On solving we get i = (V/R)(1-exp⁡((R/L)t)).

2. The steady state part in the expression of current in the R-L circuit is?
A. (V/R)(exp⁡((R/L)t))
B. (V/R)(-exp⁡((R/L)t))
C. V/R
D. R/V

Answer: C
Clarification: The steady state part in the expression of current in the R-L circuit is steady state part = V/R. When the switch S is closed, the response reaches a steady state value after a time interval.

3. In the expression of current in the R-L circuit the transient part is?
A. R/V
B. (V/R)(-exp⁡((R/L)t))
C. (V/R)(exp⁡((R/L)t))
D. V/R

Answer: B
Clarification: The expression of current in the R-L circuit has the transient part as
(V/R)(-exp⁡((R/L)t)). The transition period is defined as the time taken for the current to reach its final or steady state value from its initial value.

4. The value of the time constant in the R-L circuit is?
A. L/R
B. R/L
C. R
D. L

Answer: A
Clarification: The time constant of a function (V/R)e^-(R/L)t is the time at which the exponent of e is unity where e is the base of the natural logarithms. The term L/R is called the time constant and is denoted by ‘τ’.

5. After how many time constants, the transient part reaches more than 99 percent of its final value?
A. 2
B. 3
C. 4
D. 5

Answer: D
Clarification: After five time constants, the transient part of the response reaches more than 99 percent of its final value.

6. A series R-L circuit with R = 30Ω and L = 15H has a constant voltage V = 60V applied at t = 0 as shown in the figure. Determine the current (A. in the circuit at t = 0⁺.

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

Answer: D
Clarification: Since the inductor never allows sudden changes in currents. At t = 0⁺ that just after the initial state the current in the circuit is zero.

7. The expression of current obtained from the circuit in terms of differentiation from the circuit shown below?

A. di/dt+i=4
B. di/dt+2i=0
C. di/dt+2i=4
D. di/dt-2i=4

Answer: C
Clarification: Let the i be the current flowing through the circuit. By applying Kirchhoff’s voltage law, we get 15 di/dt+30i=60 => di/dt+2i=4.

8. The expression of current from the circuit shown below is?

A. i=2(1-e^-2t)A
B. i=2(1+e^-2t)A
C. i=2(1+e^2t)A
D. i=2(1+e^2t)A

Answer: A
Clarification: At t = 0⁺ the current in the circuit is zero. Therefore at t = 0⁺, i = 0 => 0 = c + 2 =>c = -2. Substituting the value of ‘c’ in the current equation, we have i = 2(1-e^-2t)A.

9. The expression of voltage across resistor in the circuit shown below is?

A. V_R = 60(1+e^2t)V
B. V_R = 60(1-e^-2t)V
C. V_R = 60(1-e^2t)V
D. V_R = 60(1+e^-2t)V

Answer: B
Clarification: Voltage across the resistor V_R = iR. On substituting the expression of current we get voltage across resistor = (2(1-e^-2t))×30=60(1-e^-2t)V.

10. Determine the voltage across the inductor in the circuit shown below is?
A. V_L = 60(-e^-2t)V
B. V_L = 60(e^2t)V
C. V_L = 60(e^-2t)V
D. V_L = 60(-e^2t)V

Answer: C
Clarification: Voltage across the inductor V_L = Ldi/dt. On substituting the expression of current we get voltage across the inductor = 15×(d/dt)(2(1-e^-2t)))=60(e^-2t)V.

250+ TOP MCQs on Advanced Problems on Application of Laplace Transform – 2 and Answers

Network Theory Objective Questions on “Advanced Problems on Application of Laplace Transform – 2”.

1. A capacitor of 110 V, 50 Hz is needed for AC supply. The peak voltage of the capacitor should be ____________
A. 110 V
B. 460 V
C. 220 V
D. 230 V

Answer: C
Clarification: We know that,
Peak voltage rating = 2 (rms voltage rating).
Given that, rms voltage rating = 110 V
So, Peak voltage rating = 110 X 2 V
= 220 V.

2. Given I (t) = 10[1 + sin (- t)]. The RMS value of I(t) is ____________
A. 10
B. 5
C. (sqrt{150})
D. 105

Answer: C
Clarification: Given that, I (t) = 10[1 + sin (- t)]
Now, RMS value = (sqrt{10^2 + frac{10^2}{sqrt{2}}})
= (sqrt{100+50})
= (sqrt{150}).

3. A two branch parallel circuit has a 50 Ω resistance and 10 H inductance in one branch and a 1 μF capacitor in the second branch. It is fed from 220 V ac supply, at resonance, the input impedance of the circuit is _____________
A. 447.2 Ω
B. 500 Ω
C. 235.48 Ω
D. 325.64 Ω

Answer: A
Clarification: We know that,
For a parallel resonance circuit impedance = ([frac{L}{RC}]^{0.5})
Given, R = 50 Ω, L = 10 H and C = 1 μF
= ([frac{10}{50*1}]^{0.5})
So, impedance = 447.2 Ω.

4. The impedance matrices of two, two-port network are given by [3 2; 2 3] and [15 5; 5 25]. The impedance matrix of the resulting two-port network when the two networks are connected in series is ____________
A. [3 5; 2 25]
B. [18 7; 7 28]
C. [15 2; 5 3]
D. Indeterminate

Answer: B
Clarification: Given that two impedance matrices are [3 2; 2 3] and [15 5; 5 25]. Here, the resulting impedance is the sum of the two given impedances.
So resulting impedance = [18 7; 7 28].

5. The electrical energy required to heat a bucket of water to a certain temperature is 10 kWh. If heat losses, are 10%, the energy input is ____________
A. 2.67 kWh
B. 3 kWh
C. 2.5 kWh
D. 3.5 kWh

Answer: A
Clarification: Given that, 10% of input is lost.
So, 0.90 Input = 10
Or, Input = (frac{10}{0.9}) = 11.11 kWh.

6. The current rating of a cable depends on ___________
A. Length of the cable
B. Diameter of the cable
C. Both length and diameter of the cable
D. Neither length nor diameter of the cable

Answer: B
Clarification: We know that Current rating depends only on the area of cross-section. Since the area of cross section is a function of radius, which in turn is a function of diameter, so the current rating depends only on the Diameter of the cable.

7. In an AC circuit, the maximum and minimum values of power factor can be ___________
A. 2 and 0
B. 1 and 0
C. 0 and -1
D. 1 and -1

Answer: B
Clarification: We know that, power factor is maximum and equal to 1 for a purely resistive load. Power factor is minimum and equal to zero for a purely reactive load.
Hence, in an AC circuit, the maximum and minimum values of power factor are 1 and 0 respectively.

8. In the circuit given below, the series circuit shown in figure, for series resonance, the value of the coupling coefficient, K will be?

A. 0.25
B. 0.5
C. 0.1
D. 1

Answer: A
Clarification: Mutual inductance w_m = ω k (sqrt{L_1 L_2})
Or, m = k.2.8 j²
= 4k.j
At resonance, Z = 20 – j10 + j2 + j6 + 2.4kj – 2j + 8kj = 0
Or, -2 = -8k
Or, k = (frac{1}{4}) = 0.25.

9. In an RC series circuit R = 100 Ω and X_C = 10 Ω. Which of the following is possible?
A. The current and voltage are in phase
B. The current leads the voltage by about 6°
C. The current leads the voltage by about 84°
D. The current lags the voltage by about 6°

Answer: B
Clarification: In RC circuit the current leads the voltage.
Or, θ = tan^-1 (frac{10}{100})
This is nearly equal to 6°
Hence, the current lags the voltage by about 6°.

10. The impedance of an RC series circuit is 12 Ω at f = 50 Hz. At f = 200 Hz, the impedance will be?
A. More than 12
B. Less than 3
C. More than 3 Ω but less than 12 Ω
D. More than 12 Ω but less than 24 Ω

Answer: C
Clarification: We know that the impedance Z, is given by
Z = R² + (X_C^2)
When f is made four times, X_C becomes one-fourth but R remains the same.
So, the impedance is more than 3 Ω but less than 12 Ω.

11. A 3 phase balanced supply feeds a 3-phase unbalanced load. Power supplied to the load can be measured by ___________
A. 2 Wattmeter and 1 Wattmeter
B. 2 Wattmeter and 3 Wattmeter
C. 2 Wattmeter and 2 Wattmeter
D. Only 3 Wattmeter

Answer: B
Clarification: We know that, a minimum of 2 wattmeters is required to measure a 3-phase power. Also, power can be measured by using only one wattmeter in each phase. Hence, power supplied to the load can be measured by 2 Wattmeter and 3 Wattmeter methods.

12. A series RC circuit has R = 15 Ω and C = 1 μF. The current in the circuit is 5 sin 10t. The applied voltage is _____________
A. 218200 cos (10t – 89.99°)
B. 218200 sin (10t – 89.99°)
C. 218200 sin (10t)
D. 218200 cos (10t)

Answer: B
Clarification: Given that, R = 15Ω, X_C = (frac{1}{ωC})
= (frac{10^6}{10 X 1}) = 10⁵ Ω
Now, θ = tan^-1 (frac{X_C}{R}) = 89.99°
We know that, impedance Z is given by,
Z = (sqrt{R^2 + X_C^2}) = 10² kΩ.
Hence, V = 100000(2.182).sin(10 t – 89.99°)
Or, V = 218200 sin (10t – 89.99°).

13. A capacitor stores 0.15C at 5 V. Its capacitance is ____________
A. 0.75 F
B. 0.75 μF
C. 0.03 F
D. 0.03 μF

Answer: C
Clarification: We know that, Q = CV
Given, V = 5 V, Q = 0.15 C
Hence, 0.15 = C(5)
Or, C = 0.03 F.

14. For a transmission line, open circuit and short circuit impedances are 10 Ω and 20 Ω. Then characteristic impedance is ____________
A. 100 Ω
B. 50 Ω
C. 25 Ω
D. 200 Ω

Answer: D
Clarification: We know that, the characteristic impedance Z0 is given by,
Z₀ = Z_oc Z_sc
Given that, open circuit impedance, Z_oc = 10 Ω and short circuit impedance, Z_sc = 20 Ω.
So, Z₀ = (10.20) Ω
= 200 Ω.

15. A circuit excited by voltage V has a resistance R which is in series with an inductor and a capacitor connected in parallel. The voltage across the resistor at the resonant frequency is ___________
A. 0
B. (frac{V}{2})
C. (frac{V}{3})
D. V

Answer: A
Clarification: Dynamic resistance of the tank circuit, Z_DY = (frac{L}{R_LC})
But given that R_L = 0
So, Z_DY = (frac{L}{0XC}) = ∞
Therefore current through the circuit, I = (frac{V}{∞}) = 0
∴ V_D = 0.

250+ TOP MCQs on Series-Series Connection of Two Port Network and Answers

Network Theory Multiple Choice Questions on “Series-Series Connection of Two Port Network”.

1. In the circuit given below, the value of R is ___________

A. 2.5 Ω
B. 5.0 Ω
C. 7.5 Ω
D. 10.0 Ω

Answer: C
Clarification: The resultant R when viewed from voltage source = (frac{100}{8}) = 12.5
∴ R = 12.5 – 10 || 10 = 12.5 – 5 = 7.55 Ω.

2. In the circuit given below, the number of chords in the graph is ________________

A. 3
B. 4
C. 5
D. 6

Answer: B
Clarification: Given that, b = 6, n = 3
Number of Links is given by, b – n + 1
= 6 – 3 + 1 = 4.

3. In the circuit given below, the current through the 2 kΩ resistance is _____________

A. Zero
B. 1 mA
C. 2 mA
D. 6 mA

Answer: A
Clarification: We know that when a Wheatstone bridge is balanced, no current will flow through the middle resistance.
Here, (frac{R_1}{R_2} = frac{R_3}{R_4})
Since, R₁ = R₂ = R₃ = R₄ = 1 kΩ.

4. How many incandescent lamps connected in series would consume the same total power as a single 100 W/220 V incandescent lamp. The rating of each lamp is 200 W/220 V?
A. Not possible
B. 4
C. 3
D. 2

Answer: D
Clarification: In series power = (frac{1}{P})
Now, (frac{1}{P} = frac{1}{P_1} + frac{1}{P_2})
= (frac{1}{200} + frac{1}{200})
Or, P = (frac{200}{2}) = 100 W.

5. Two networks are connected in series parallel connection. Then, the forward short-circuit current gain of the network is ____________
A. Product of Z-parameter matrices
B. Sum of h-parameter matrices
C. Sum of Z-parameter matrices
D. Product of h-parameter matrices

Answer: B
Clarification: The forward short circuit current gain is given by,
h₂₁ = (frac{I_2 (s)}{I_1 (s)}), when V₂ = 0
So, when the two networks are connected in series parallel combination,
[h₁₁, h₁₂; h₂₁, h₂₂] = [h’₁₁ + h’₁₁, h’₁₂ + h’₁₂; h’₂₁ + h’₂₁, h’₂₂ + h’₂₂]
So, h₂₁ of total network will be sum of h parameter matrices.

6. The condition for a 2port network to be reciprocal is ______________
A. Z₁₁ = Z₂₂
B. BC – AD = -1
C. Y₁₂ = -Y₂₁
D. h₁₂ = h₂₁

Answer: B
Clarification: If the network is reciprocal, then the ratio of the response transform to the excitation transform would not vary after interchanging the position of the excitation.

7. The relation AD – BC = 1, (where A, B, C and D are the elements of a transmission matrix of a network) is valid for ___________
A. Both active and passive networks
B. Passive but not reciprocal networks
C. Active and reciprocal networks
D. Passive and reciprocal networks

Answer: D
Clarification: AD – BC = 1, is the condition for reciprocity for ABCD parameters, which shows that the relation is valid for reciprocal network. The ABCD parameters are obtained for the network which consists of resistance, capacitance and inductance, which indicates that it is a passive network.

8. For a 2 port network, the transmission parameters are given as 10, 9, 11 and 10 corresponds to A, B, C and D. The correct statement among the following is?
A. Network satisfies both reciprocity and symmetry
B. Network satisfies only reciprocity
C. Network satisfies only symmetry
D. Network satisfies neither reciprocity nor symmetry

Answer: A
Clarification: Here, A = 10, B = 9, C = 11, D = 10
∴ A = D
∴ Condition for symmetry is satisfied.
Also, AD – BC = (10) (10) – (9) (11)
= 100 – 99 = 1
Therefore the condition of reciprocity is satisfied.

9. In the circuit given below, the equivalent capacitance is ______________

A. (frac{C}{4})
B. (frac{5C}{13})
C. (frac{5C}{2})
D. 3C

Answer: B
Clarification: The equivalent capacitance by applying the concept of series-parallel combination of the capacitance is,
(frac{1}{C_{EQ}} = frac{1}{C} + frac{1}{C} + frac{1}{5C/3})
= (frac{1}{C} + frac{1}{C} + frac{3}{5C} = frac{1}{C}(frac{5+5+3}{5}))
Or, C_EQ = (frac{5C}{13})
123 c Energy delivered during talk time
E = ∫ V(t)I(t) dt
Given, I (t) = 2 A = constant = 2 ∫ V(t)dt
= 2 × Shaded area
= 2 × (frac{1}{2}) × (10 + 12) × 60 × 10
= 13.2 kJ.

10. In the circuit given below, the 60 V source absorbs power. Then the value of the current source is ____________

A. 10 A
B. 13 A
C. 15 A
D. 18 A

Answer: A
Clarification: Given that, 60 V source is absorbing power, it means that current flow from positive to negative terminal in 60 V source.
Applying KVL, we get, I + I₁ = 12 A ……………… (1)
Current source must have the value of less than 12 A to satisfy equation (1).

11. In the circuit given below, the number of node and branches are ______________

A. 4 and 5
B. 4 and 6
C. 5 and 6
D. 6 and 4

Answer: B
Clarification: In the given graph, there are 4 nodes and 6 branches.
Twig = n – 1 = 4 – 1 = 3
Link = b – n + 1 = 6 – 4 + 1 = 3.

12. A moving coil of a meter has 250 turns and a length and depth of 40 mm and 30 mm respectively. It is positioned in a uniform radial flux density of 450 mT. The coil carries a current of 160 mA. The torque on the coil is?
A. 0.0216 N-m
B. 0.0456 N-m
C. 0.1448 N-m
D. 1 N-m

Answer: A
Clarification: Given, N = 250, L = 40 × 10^-3, d = 30 × 10^-3m, I = 160 × 10^-3A, B = 450 × 10^-3 T
Torque = 250 × 450 × 10^-3 × 40 × 10^-3 × 30 × 10^-3 × 160 × 10^-3
= 200 × 10^-6 N-m = 0.0216 N-m.

13. In the circuit given below, the equivalent inductance is ____________

A. L₁ + L₂ – 2M
B. L₁ + L₂ + 2M
C. L₁ + L₂ – M
D. L₁ + L₂

Answer: A
Clarification: Since, in one inductor current is leaving to dot and in other inductor current is entering to dot.
So, L_EQ = L₁ + L₂ – 2M.

14. In the figure given below, the pole-zero plot corresponds to _____________

A. Low-pass filter
B. High-pass filter
C. Band-pass filter
D. Notch filter

Answer: D
Clarification: In pole zero plot the two transmission zeroes are located on the jω-axis, at the complex conjugate location, and then the magnitude response exhibits a zero transmission at ω – ω_C.

15. In the circuit given below, the maximum power that can be transferred to the resistor R_L is _____________

A. 1 W
B. 10 W
C. 0.25 W
D. 0.5 W

Answer: C
Clarification: For maximum power transfer to the load resistor R_L, R_L must be equal to 100 Ω.
∴ Maximum power = (frac{V^2}{4R_L})
= (frac{10^2}{4 ×100}) = 0.25 W.