# GATE 2016 EE – Set 2 – Complete Solutions # GATE 2016 EE – Set 2 – Complete Solutions

GATE 2016 EE – Set 2 – Complete Solutions,Answer Key & Full Solutions to GATE 2017 Questions Papers for All branches .Full Solutions to GATE 2017 Questions Papers ## GATE 2016 EE – Set 2 – Complete Solutions search engine Keywords Thesis 123

• GATE 2016 EE – Set 2 – Complete Solutions
• gate paper
• gate question paper
• gate 2017 question paper with solution
• gate previous papers
• gate solved papers/li>
• gate 2017 question paper
• gate question bank
• gate question paper with solution
• gate electrical engineering
• gate model papers
• gate sample papers
• gate 2017 key
• gate previous year papers
• gate papers for electronics and communication
• gate previous year question papers with solutions for ece
• gate paper for mechanical engineering
• gate online test
• gate previous year question papers with solutions
• gate solved question papers
• gate mechanical solved papers
• gate previous year question papers with solutions for cse
• gate test papers
• gate civil engineering solved papers pdf
• gate online coaching
• gate solved papers for mechanical engineering
• made easy gate previous papers
• gate question bank for mechanical engineering
• gate previous papers with solutions for mechanical
• gate ece solved papers
• gate question bank for mechanical
• gate civil previous papers with solutions
• made easy solved paper of gate
• gate engineering mathematics previous years question papers with solutions
• gate previous papers with solutions for cse
• gate ee previous papers
• gate previous year papers for mechanical
• gate previous year question papers with solutions for engineers
• gate 10 years solved papers

Q1. The output expression for the Karnaugh map shown below is (A) $$A+\bar{B}$$     (B) $$A+\bar{C}$$    (C) $$\bar{A}+\bar{C}$$       (D) $$\bar{A} + C$$

Solution: (B)

Q2. The circuit shown below is an example of a (A) Low pass filter    (B) Band pass filter    (C) High pass filter    (D) Notch filter

Solution: (A)

Q3. The following figure shows the connection of an ideal transformer with primary to secondary turns ratio of 1:100. The applied primary voltage is 100 V (rms), 50 Hz, AC. The rms value of the current I, in ampere, is ______. Solution: Key = 9.5 to 10.5

Q4. Consider a causal LTI system characterized by differential equation $$\frac{\mathrm{d}y\left ( t \right ) }{\mathrm{d} t}+\frac{1}{6}y\left ( t \right )=3x\left ( t \right )$$. The response of the system to the input $$x\left ( t \right )=3e^{\frac{-t}{3}}u\left ( t \right )$$, where u(t) denotes the unit step function, is

(A) $$9e^{\frac{-t}{3}}u\left ( t \right )$$                                                                            (B) $$9e^{\frac{-t}{6}}u\left ( t \right )$$

(C) $$9e^{\frac{-t}{3}}u\left ( t \right )-6e^{\frac{-t}{6}}u\left ( t \right )$$        (D) $$54e^{\frac{-t}{6}}u\left ( t \right )-54e^{\frac{-t}{3}}u\left ( t \right )$$

Solution: (D)

Q5. Suppose the maximum frequency in a band-limited signal x(t) is 5 kHz. Then, the maximum frequency in $$x(t)\cos (2000\pi t)$$, in kHz, is ________.

Solution: Key = 6

Q6. Consider the function $$f(z)=z+z^{\ast }$$ where z is a complex variable and $$z^{\ast }$$ denotes its complex conjugate. Which one of the following is TRUE?

(A) f(z) is both continuous and analytic         (B) ݂f(z) is continuous but not analytic

(C) ݂f(z) is not continuous but is analytic        (D) ݂f(z) is neither continuous nor analytic

Solution: (B)

Q7. A 3 x 3 matrix P is such that, $$P^{3}=P$$. Then the eigenvalues of P are

(A) 1, 1, -1                                                     (B) 1, 0.5+j0.866, 0.5-j0.866

(C) 1, -0.5+j0.866, -0.5-j0.866            (D) 0, 1, -1

Solution: (D)

Q8. The solution of the differential equation, for $$t > 0, y^{“}(t)+2y^{‘}(t)+y(t)=0$$ with initial conditions $$y(0)=0$$ and $$y^{‘}(0)=1$$, is (u(t) denotes the unit step function),

(A) $$te^{-t}u(t)$$                          (B) $$(e^{-t}-te^{-t})u(t)$$

(C) $$(e^{-t}+te^{-t})u(t)$$         (D) $$e^{-t}u(t)$$

Solution: (A)

9. The value of the line integral $$\int_{c}(2xy^{2}dx+2x^{2}ydy+dz)$$ along a path joining the origin (0,0,0) and the point (1,1,1) is

(A) 0                    (B) 2                    (C) 4                    (D) 6

Solution: (B)

Q10. Let f(x) be a real, periodic function satisfying f(-x) = – f(x). The general form of its Fourier series representation would be

(A) $$f(x)=a_{0}+\sum_{k=1}^{\infty }a_{k}\cos (kx)$$

(B) $$f(x)=\sum_{k=1}^{\infty }b_{k}\sin (kx)$$

(C) $$f(x)=a_{0}+\sum_{k=1}^{\infty }a_{2k}\cos (kx)$$

(D) $$f(x)=\sum_{k=0}^{\infty }a_{2k+1}\sin (2k+1)x$$

Solution: (B)

Q11. A resistance and a coil are connected in series and supplied from a single phase, 100 V, 50 Hz ac source as shown in the figure below. The rms values of plausible voltages across the resistance $$(V_{R})$$ and coil $$(V_{C})$$ respectively, in volts, are (A) 65, 35          (B) 50, 50          (C) 60, 90          (D) 60, 80

Solution: (D)

Q12. The voltage (V) and current (A) across a load are as follows.

$$V(t)=100\sin (\omega t)$$ and $$I(t)=10\sin (\omega t-60)+2\sin (3\omega t)+5\sin (5\omega t)$$

The average power consumed by the load, in W, is _________.

Solution: Key = 249 to 251

Q13. A power system with two generators is shown in the figure below. The system (generators, buses and transmission lines) is protected by six overcurrent relays $$R_{1}$$ to $$R_{6}$$. Assuming a mix of directional and nondirectional relays at appropriate locations, the remote backup relays for $$R_{4}$$ are (A) $$R_{1}$$, $$R_{2}$$          (B) $$R_{2}$$, $$R_{6}$$          (C) $$R_{2}$$, $$R_{5}$$          (D) $$R_{1}$$, $$R_{6}$$

Solution: (D)

Q14. A power system has 100 buses including 10 generator buses. For the load flow analysis using Newton-Raphson method in polar coordinates, the size of the Jacobian is

(A) 189 x 189          (B) 100 x 100          (C) 90 x 90          (D) 180 x 180

Solution: (A)

Q15. The inductance and capacitance of a 400 kV, three-phase, 50 Hz lossless transmission line are 1.6 mH/km/phase and 10 nF/km/phase respectively. The sending end voltage is maintained at 400 kV. To maintain a voltage of 400 kV at the receiving end, when the line is delivering 300 MW load, the shunt compensation required is

(A) Capacitive          (B) Inductive          (C) Resistive           (D) Zero

Solution: (B)

Q16. A parallel plate capacitor filled with two dielectrics is shown in the figure below. If the electric field in the region A is 4 kV/cm, the electric field in the region B, in kV/cm, is (A) 1          (B) 2          (C) 4          (D) 16

Solution: (C)

Q17. A 50 MVA, 10 kV, 50 Hz, star-connected, unloaded three-phase alternator has a synchronous reactance of 1 p.u. and a sub-transient reactance of 0.2 p.u. If a 3-phase short circuit occurs close to the generator terminals, the ratio of initial and final values of the sinusoidal component of the short circuit current is __________.

Solution: Key = 4.9 to 5.1

Q18. Consider a linear time-invariant system with transfer function $$H(S)=\frac{1}{S+1}$$. If the input is $$\cos (t)$$ and the steady state output is $$A\cos (t+\alpha )$$ then the value of A is __________.

Solution: Key = 0.69 to 0.72

Q19. A three-phase diode bridge rectifier is feeding a constant DC current of 100 A to a highly inductive load. If three-phase, 415 V, 50 Hz AC source is supplying to this bridge rectifier then the rms value of the current in each diode, in ampere, is _________.

Solution: Key = 57 to 58

Q20. A buck-boost DC-DC converter, shown in the figure below, is used to convert 24 V battery voltage to 36 V DC voltage to feed a load of 72 W. It is operated at 20 kHz with an inductor of 2 mH and output capacitor of $$1000\mu F$$. All devices are considered to be ideal. The peak voltage across the solid-state switch (S), in volt, is _________. Solution: Key = 59.5 to 60.5

Q21. For the network shown in the figure below, the frequency (in rad/s) at which the maximum phase lag occurs is, __________. Solution: Key = 0.30 to 0.33

Q22. The direction of rotation of a single-phase capacitor run induction motor is reversed by

(A) interchanging the terminals of the AC supply.

(B) interchanging the terminals of the capacitor.

(C) interchanging the terminals of the auxiliary winding.

(D) interchanging the terminals of both the windings.

Solution: (C)

Q23. In the circuit shown below, the voltage and current sources are ideal. The voltage $$V_{out}$$ across the current source, in volts, is (A) 0           (B) 5          (C) 10          (D) 20

Solution: (D)

Q24. The graph associated with an electrical network has 7 branches and 5 nodes. The number of independent KCL equations and the number of independent KVL equations, respectively, are

(A) 2 and 5          (B) 5 and 2          (C) 3 and 4         (D) 4 and 3

Solution: Key = (D)

Q25. Two electrodes, whose cross-sectional view is shown in the figure below, are at the same potential. The maximum electric field will be at the point (A) A          (B) B          (C) C          (D) D

Solution: (A)

Q26. The Boolean expression $$\overline{(a+\bar{b}+c+\bar{d})+(b+\bar{c})}$$ simplifies to

(A) 1          (B) $$\overline{a\cdot b}$$          (C) $$a\cdot b$$          (D) 0

Solution: (D)

Q27. For the circuit shown below, taking the opamp as ideal, the output voltage $$V_{out}$$ in terms of the input voltages $$V_{1}, V_{2}$$ and $$V_{3}$$ is (A) $$1.8V_{1}+7.2V_{2}-V_{3}$$

(B) $$2V_{1}+8V_{2}-9V_{3}$$

(C) $$7.2V_{1}+1.8V_{2}-V_{3}$$

(D) $$8V_{1}+2V_{2}-9V_{3}$$

Solution: (D)

Q28. Let $$x_{1}(t)\leftrightarrow X_{1}(\omega )$$ and $$x_{2}(t)\leftrightarrow X_{2}(\omega )$$ be two signals whose Fourier Transforms are as shown in the figure below. In the figure, $$h(t)=e^{-2\left | t \right |}$$ denotes the impulse response. For the system shown above, the minimum sampling rate required to sample y(t), so that y(t) can be uniquely reconstructed from its samples, is

(A) $$2B_{1}$$          (B) $$2(B_{1}+B_{2})$$          (C) $$4(B_{1}+B_{2})$$          (D) $$\infty$$

Solution: (B)

Q29. The value of the integral $$\int_{-\infty }^{\infty }\left ( \frac{\sin 2\pi t}{\pi t} \right )dt$$ is equal to

(A) 0          (B) 0.5          (C) 1          (D) 2

Solution: (D)

Q30. Let y(x) be the solution of the differential equation $$\frac{\mathrm{d} ^{2}y}{\mathrm{d} x^{2}}-4\frac{\mathrm{d} y}{\mathrm{d} x}+4y=0$$ with initial conditions $$y(0)=0$$ and $$\left [ \frac{\mathrm{d} y}{\mathrm{d} x} \right ]_{x=0}=1$$. Then the value of y(1) is _________.

Solution: Key = 7.0 to 7.5

Q31. The line integral of the vector field $$F=5xz\hat{i}+(3x^{2}+2y)\hat{j}+x^{2}z\hat{k}$$ along a path from (0, 0, 0) to (1, 1, 1) parametrized by $$(t,t^{2},t)$$ is ________.

Solution: Key = 4.40 to 4.45

Q32. Let $$P=\begin{bmatrix}3 & 1\\ 1 & 3\end{bmatrix}$$. Consider the set S of all vectors $$\binom{x}{y}$$ such that $$a^{2}+b^{2}=1$$ where $$\binom{a}{b}=P\binom{x}{y}$$. Then S is

(A) A circle of radius $$\sqrt{10}$$

(B) A circle of radius $$\frac{1}{\sqrt{10}}$$

(C) An ellipse with major axis along $$\binom{1}{1}$$

(D) An ellipse with minor axis along $$\binom{1}{1}$$

Solution: (D)

Q33. Let the probability density function of a random variable, X, be given as: $$f_{x}(x)=\frac{3}{2}e^{-3x}u(x)+ae^{4x}u(-x)$$, where u(x) is the nit step function. Then the value of ‘a’ and Prob$${X\leq 0}$$  respectively, are

(A) 2, 1/2          (B) 4, 1/2          (C) 2, 1/4          (D) 4, 1/4

Solution: (A)

Q34. The driving point input impedance seen from the source $$V_{S}$$ of the circuit shown below, in $$\Omega$$, is ______. Solution: Key = 19.5 to 20.5

Q35. The z-parameters of the two port network shown in the figure are $$Z_{11}=40\Omega, Z_{12}=60\Omega, Z_{21}=80\Omega$$ and $$Z_{22}=100\Omega$$. The average power delivered to $$R_{L}=20\Omega$$, in watts, is _______. Solution: Key = 34.0 to 36.0

Q36. In the balanced 3-phase, 50 Hz, circuit shown below, the value of inductance (L) is 10 mH. The value of the capacitance (C) for which all the line currents are zero, in millifarads, is ___________. Solution: Key = 2.9 to 3.1

Q37. In the circuit shown below, the initial capacitor voltage is 4 V. Switch $$S_{1}$$ is closed at t = 0. The charge (in $$\mu C$$) lost by the capacitor from $$t=25\mu s$$ to $$t=100\mu s$$ is ______. Solution: Key = 6.8 to 7.2

Q38. The single line diagram of a balanced power system is shown in the figure. The voltage magnitude at the generator internal bus is constant and 1.0 p.u. The p.u. reactances of different components in the system are also shown in the figure. The infinite bus voltage magnitude is 1.0 p.u. A three phase fault occurs at the middle of line 2. The ratio of the maximum real power that can be transferred during the pre-fault condition to the maximum real power that can be transferred under the faulted condition is _________. Solution: Key = 2.20 to 2.35

Q39. The open loop transfer function of a unity feedback control system is given by $$G(s)=\frac{K(s+1)}{s(1+Ts)(1+2s)}, K> 0, T> 0$$. The closed loop system will be stable if,

(A) $$0< T< \frac{4(K+1)}{K-1}$$

(B) $$0< K< \frac{4(T+2)}{T-2}$$

(C) $$0< K< \frac{T+2}{T-2}$$

(D) $$0< T< \frac{8(K+1)}{K-1}$$

Solution: (C)

Q40. At no load condition, a 3-phase, 50 Hz, lossless power transmission line has sending-end and receiving-end voltages of 400 kV and 420 kV respectively. Assuming the velocity of traveling wave to be the velocity of light, the length of the line, in km, is ____________.

Solution: Key = 294.0 to 298.0

Q41. The power consumption of an industry is 500 kVA, at 0.8 p.f. lagging. A synchronous motor is added to raise the power factor of the industry to unity. If the power intake of the motor is 100 kW, the p.f. of the motor is ___________.

Solution: Key = 0.31 to 0.33

Q42. The flux linkage $$(\lambda )$$ and current (i) relation for an electromagnetic system is $$\lambda =\frac{\sqrt{i}}{g}$$ . When i = 2A and g (air-gap length) = 10 cm, the magnitude of mechanical force on the moving part, in N, is _________.

Solution: 141.4

Q43. The starting line current of a 415 V, 3-phase, delta connected induction motor is 120 A, when the rated voltage is applied to its stator winding. The starting line current at a reduced voltage of 110 V, in ampere, is _________.

Solution:Key = 31.0 to 33.0

Q44. A single-phase, 2 kVA, 100/200 V transformer is reconnected as an auto-transformer such that its kVA rating is maximum. The new rating, in kVA, is ______.

Solution: Key = 5.9 to 6.1

Q45. A full-bridge converter supplying an RLE load is shown in figure. The firing angle of the bridge converter is $$120^{\circ}$$ The supply voltage $$V_{m}(t)=200\pi \sin (100\pi t)V$$, $$R=20\Omega$$, $$E=800V$$. The inductor L is large enough to make the output current $$I_{L}$$ a smooth dc current. Switches are lossless. The real power fed back to the source, in kW, is __________. Solution: Key = 5.9 to 6.1

Q46. A three-phase Voltage Source Inverter (VSI) as shown in the figure is feeding a delta connected resistive load of $$30\Omega /phase$$. If it is fed from a 600 V battery, with $$180^{\circ}$$ conduction of solid-state devices, the power consumed by the load, in kW, is __________. Solution: Key = 23.0 to 25.0

Q47. A DC-DC boost converter, as shown in the figure below, is used to boost 360V to 400 V, at a power of 4 kW. All devices are ideal. Considering continuous inductor current, the rms current in the solid state switch (S), in ampere, is _________. Solution: Key = 3.0 to 4.0

Q48. A single-phase bi-directional voltage source converter (VSC) is shown in the figure below. All devices are ideal. It is used to charge a battery at 400 V with power of 5 kW from a source $$V_{s}$$= 220 V (rms), 50 Hz sinusoidal AC mains at unity p.f. If its AC side interfacing inductor is 5 mH and the switches are operated at 20 kHz, then the phase shift $$(\delta )$$ between AC mains voltage $$V_{s}$$ and fundamental AC rms VSC voltage $$V_{C1}$$ in degree, is _________. Solution: Key = 9.1 to 9.3

Q49. Consider a linear time invariant system $$\dot{x}=Ax$$ with initial condition x(0)  and t = 0. Suppose $$\alpha$$ and $$\beta$$ are eigenvectors of (2 x 2) matrix A corresponding to distinct eigenvalues $$\lambda _{1}$$ and $$\lambda _{2}$$ respectively.  Then the response Then the response x(t) of the system due to initial condition x(0) = $$\alpha$$ is

(A) $$e^{\lambda _{1}t}\alpha$$          (B) $$e^{\lambda _{2}t}\beta$$

(C) $$e^{\lambda _{2}t}\alpha$$          (D) $$e^{\lambda _{1}t}\alpha + e^{\lambda _{2}t}\beta$$

Solution: (A)

Q50. A second-order real system has the following properties:

a) the damping ratio $$\zeta =0.5$$ and undamped natural frequency $$\omega _{n}=10 rad/s$$

b) the steady state value of the output, to a unit step input, is 1.02.

The transfer function of the system is

(A) $$\frac{1.02}{s^{2}+5s+100}$$          (B) $$\frac{102}{s^{2}+10s+100}$$

(C) $$\frac{100}{s^{2}+10s+100}$$         (D) $$\frac{102}{s^{2}+5s+100}$$

Solution: (B)

Q51. Three single-phase transformers are connected to form a delta-star three-phase transformer of 110 kV/ 11 kV. The transformer supplies at 11 kV a load of 8 MW at 0.8 p.f. lagging to a nearby plant. Neglect the transformer losses. The ratio of phase currents in delta side to star side is

(A) $$1:10\sqrt{3}$$          (B) $$10\sqrt{3}:1$$          (C) $$1:10$$          (D) $$\sqrt{3}:10$$

Solution: (A)

Q52. The gain at the breakaway point of the root locus of a unity feedback system with open loop transfer function $$G(s)=\frac{Ks}{(s-1)(s-4)}$$ is

(A) 1          (B) 2          (C) 5          (C) 9

Solution: (A)

Q53. Two identical unloaded generators are connected in parallel as shown in the figure. Both the generators are having positive, negative and zero sequence impedances of j0.4 p.u., j0.3 p.u. and j0.15 p.u., respectively. If the pre-fault voltage is 1 p.u., for a line-to-ground (L-G) fault at the terminals of the generators, the fault current, in p.u., is ___________. Solution: Key = 5.5 to 6.5

Q54. An energy meter, having meter constant of 1200 revolutions/kWh, makes 20 revolutions in 30 seconds for a constant load. The load, in kW, is __________.

Solution: Key = 1.9 to 2.1

Q55. A rotating conductor of 1 m length is placed in a radially outward (about the z-axis) magnetic flux density (B) of 1 Tesla as shown in figure below. Conductor is parallel to and at 1 m distance from the z-axis. The speed of the conductor in r.p.m. required to induce a voltage of 1 V across it, should be __________. Solution: Key = 9.4 to 9.7