GATE ECE 2004 | Sinusoidal Steady State Response Question 38 | Network Theory

For the circuit shown in figure, the time constant $$RC = 1$$ $$ms$$. The input voltage is $${v_i}\left( t \right) = \sqrt 2 \,\sin \,{10^3}t$$. The output voltage $${v_0}\left( t \right)$$ is equal to GATE ECE 2004 Network Theory - Sinusoidal Steady State Response Question 41 English

GATE ECE 2004 Network Theory - Sinusoidal Steady State Response Question 41 English

$$\sin \left( {{{10}^3}t - {{45}^0}} \right)$$

$$\sin \left( {{{10}^3}t + {{45}^0}} \right)$$

$$\sin \left( {{{10}^3}t - {{53}^0}} \right)$$

$$\sin \left( {{{10}^3}t + {{53}^0}} \right)$$

GATE ECE 2003

MCQ (Single Correct Answer)

-0.3

A series RLC circuit has a resonance frequency of 1 kHz and a quality factor Q = 100. If each R, L and C is doubled from its original value, the new Q of the circuit is

100

200

GATE ECE 2000

MCQ (Single Correct Answer)

-0.3

The circuit of Fig. represents a GATE ECE 2000 Network Theory - Sinusoidal Steady State Response Question 67 English

Low pass filter

High pass filter

Band pass filter

Band reject filter

GATE ECE 1998

MCQ (Single Correct Answer)

-0.3

The parallel $$RLC$$ circuit shown in figure is in resonance. In this circuit GATE ECE 1998 Network Theory - Sinusoidal Steady State Response Question 43 English

GATE ECE 1998 Network Theory - Sinusoidal Steady State Response Question 43 English

$$\left| {{{\rm I}_R}} \right| < 1m{\rm A}$$

$$\left| {{{\rm I}_R} + {{\rm I}_L}} \right| > 1m{\rm A}$$

$$\left| {{{\rm I}_R} + {{\rm I}_C}} \right| < 1m{\rm A}$$

$$\left| {{{\rm I}_L} + {{\rm I}_C}} \right| > 1m{\rm A}$$

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GATE ECE Subjects

Signals and Systems

Network Theory

Control Systems

Digital Circuits

General Aptitude

Electronic Devices and VLSI

Analog Circuits

Engineering Mathematics

Microprocessors

Communications

Electromagnetics