Network Theory Multiple Choice Questions on “Problems Involving Dot Conventions”.
1. The current through an electrical conductor is 1A when the temperature of the conductor 0°C and 0.7 A when the temperature is 100°C. The current when the temperature of the conductor is 1200°C is ___________
A. 0.08 A
B. 0.16 A
C. 0.32 A
D. 0.64 A
Answer: B
Clarification: (frac{1}{0.7} = frac{R_O (1+αt)}{R_O})
= 1 + α100
∴α = 0.0043 per °C
Current at 1200 °C is given by, (frac{1}{I} = frac{R_O (1+α1200)}{R_O})
= 1 + α1200
= 1 + 0.0043 × 1200 = 6.16
∴ I = (frac{1}{6.16}) = 0.16 A.
2. In the circuit given below, the equivalent capacitance is ____________
A. 1.625 F
B. 1.583 F
C. 0.583 F
D. 0.615 F
Answer: D
Clarification: CCB = (left(frac{C_2 C_3}{C_2+ C_3}right)) + C5 = 1.5 F
Now, CAB =(left(frac{C_1 C_{CB}}{C_1+ C_{CB}}right)) + C6 = 1.6 F
CXY = (frac{C_{AB} × C_4}{C_{AB} + C_4}) = 0.615 F.
3. In the circuit given below, the equivalent capacitance is ______________
A. 3.5 μF
B. 1.2 μF
C. 2.4 μF
D. 4.05 μF
Answer: D
Clarification: The 2.5 μF capacitor is in parallel with 1 μF capacitor and this combination is in series with 1.5 μF.
Hence, C1 = (frac{1.5(2.5+1)}{1.5+2.5+1})
= (frac{5.25}{5}) = 1.05
Now, C1 is in parallel with the 3 μF capacitor.
∴ CEQ = 1.05 + 3 = 4.05 μF.
4. In the circuit given below, the voltage across A and B is?
A. 13.04 V
B. 17.84 V
C. 12 V
D. 10.96 V
Answer: B
Clarification: Loop current I1 = (frac{6}{10}) = 0.6 A
I2 = (frac{12}{14}) = 0.86 A
VAB = (0.6) (4) + 12 + (0.86) (4)
= 2.4 + 12 + 3.44
= 17.84 V.
5. In the figure given below, the voltage source provides the circuit with a voltage V. The number of non-planar graph of independent loop equations is ______________
A. 8
B. 12
C. 7
D. 5
Answer: D
Clarification: The total number of independent loop equations are given by L = B – N + 1 where,
L = number of loop equations
B = number of branches = 12
N = number of nodes = 8
∴ L = 12 – 8 + 1 = 5.
6. When a DC voltage is applied to an inductor, the current through it is found to build up in accordance with I = 20(1-e-50t). After the lapse of 0.02 s, the voltage is equal to 2 V. What is the value of inductance?
A. 2 mH
B. 5.43 mH
C. 1.54 mH
D. 0.74 mH
Answer: B
Clarification: VL = L(frac{dI}{dt})
Where, I = 20(1-e-50t)
Therefore, VL = L(frac{d 20(1-e^{-50t})}{dt})
= L × 20 × 50e-50t
At t = 0.02 s, VL = 2 V
∴ L = (frac{2}{20 × 50 × e^{-50×0.02}})
= 5.43 μH.
7. An air capacitor of capacitance 0.005 μF is connected to a direct voltage of 500 V. It is disconnected and then immersed in oil with a relative permittivity of 2.5. The energy after immersion is?
A. 275 μJ
B. 250 μJ
C. 225 μJ
D. 625 μJ
Answer: B
Clarification: E = (frac{1}{2}) CV2
Or, C = (frac{ε_0 ε_r A}{d} = ϵ_r (frac{ε_0 A}{d}))
= 2.5 × 0.005 × 10-6
∴ CNEW = 12.5 × 10-9 F
Now, q = CV = 0.005 × 10-6 × 500 = 2.5 × 10-6
VNEW = (frac{q} {C_{NEW}})
= (frac{2.5 × 10^{-6}}{12.5 × 10^{-9}}) VNEW = 200
E = (frac{1}{2}) CV2
= (frac{1}{2}) × 12.5 × 10-9 × (200)2
= 250 μJ.
8. The resistance of copper motor winding at t=20°C is 3.42 Ω. After extended operation at full load, the motor windings measures 4.22 Ω. If the temperature coefficient is 0.0426, what is the rise in temperature?
A. 60°C
B. 45.2°C
C. 72.9°C
D. 10.16°C
Answer: D
Clarification: Given that, R1 = 3.42 Ω
T1 = 20° and α = 0.0426
R2 = 4.22 Ω
Now, (frac{R_1}{1 + αT_1} = frac{R_2}{1 + αT_2})
Or, (frac{3.42}{1 + 0.0426 × 20} = frac{4.22}{1 + 0.0426 T_2})
∴ Rise in temperature = T2 – T1
= 30.16 – 20
= 10.16°C.
9. A capacitor of capacitance 50 μF is connected in parallel to another capacitor of capacitance 100 μF. They are connected across a time-varying voltage source. At a particular time, the current supplied by the source is 5 A. The magnitude of instantaneous current through the capacitor of capacitance 50 μF is?
A. 1.57 A
B. 1.87 A
C. 1.67 A
D. 2.83 A
Answer: C
Clarification: As the capacitors are in parallel, then the voltage V is given by,
V = (frac{1}{C_1} int I_1 ,dt )
∴ I1 = C1 (frac{dV}{dt})
That is, (frac{I_1}{I_2} = frac{C_1}{C_2} = frac{50}{100} = frac{1}{2}) ………………….. (1)
Also, I1 + I2 = 5 A ………………………….. (2)
Solving (1) and (2), we get, I1 = 1.67 A.
10. A capacitor of capacitance 50 μF is connected in parallel to another capacitor of capacitance 100 μF. They are connected across a time-varying voltage source. At a particular time, the current supplied by the source is 5 A. The magnitude of instantaneous current through the capacitor of capacitance 100 μF is?
A. 2.33 A
B. 3.33 A
C. 1.33 A
D. 4.33 A
Answer: B
Clarification: As the capacitors are in parallel, then the voltage V is given by,
V = (frac{1}{C_2} int I_2 ,dt )
∴ I2 = C2 (frac{dV}{dt})
That is, (frac{I_1}{I_2} = frac{C_1}{C_2} = frac{50}{100} = frac{1}{2}) ………………….. (1)
Also, I1 + I2 = 5 A ………………………….. (2)
Solving (1) and (2), we get, I2 = 3.33 A.
11. In the circuit given below, the resonant frequency is _______________
A. (frac{1}{2sqrt{2} π}) Hz
B. (frac{1}{2π}) Hz
C. (frac{1}{4π}) Hz
D. (frac{1}{sqrt{2}2π}) Hz
Answer: C
Clarification: IEQ = L1 + L2 + 2M
LEQ = 1 + 2 + 2 × (frac{1}{2}) = 4 H
∴ FO = (frac{1}{2πsqrt{LC}} )
= (frac{1}{2πsqrt{4 × 1}} )
= (frac{1}{4π}) Hz.
12. In a series resonant circuit, VC = 300 V, VL = 300 V and VR = 100 V. What is the value of the source voltage?
A. Zero
B. 100 V
C. 350 V
D. 200 V
Answer: B
Clarification: As VC and VL are equal, then XC is equal to XL and both the voltages are then cancelled out.
That is VS = VR
∴ VS = 100 V.
13. For the circuit given below, what is the value of the Q factor for the inductor?
A. 4.74
B. 4.472
C. 4.358
D. 4.853
Answer: C
Clarification: QIN = (sqrt{frac{L}{CR^2} – 1})
= (sqrt{frac{1}{2 × 5^2 × 10^{-3} – 1}})
= (sqrt{frac{1}{50 × 10^{-3} – 1}})
= (sqrt{19}) = 4.358.
14. In the circuit given below, the value of the voltage source E is _______________
A. -65 V
B. 40 V
C. -60 V
D. 65 V
15. In the circuit given below, bulb X uses 48 W when lit, bulb Y uses 22 W when lit and bulb Z uses 14.4 W when lit. The number of additional bulbs in parallel to this circuit, that would be required to below the fuse is _______________
A. 4
B. 5
C. 6
D. 7
Answer: A
Clarification: IX = (frac{48}{12}) = 4 A
IY = (frac{22}{12}) = 1.8 A
IZ = (frac{14.4}{12}) = 1.2 A
Current required to below the fuse = 20 A
∴ Additional bulbs must draw current = 20 – (4 + 18 + 1.2)
= 20 – 7 = 13
∴ Number of additional bulbs required = (frac{13}{3}) = 4.33
So, 4 additional bulbs are required.