GATE ECE 2022 | Sinusoidal Steady State Response Question 1 | Network Theory

GATE ECE 2022

MCQ (Single Correct Answer)

-0.33

For the circuit shown, the locus of the impedance Z(j$$\omega$$) is plotted as $$\omega$$ increases from zero to infinity. The values of R₁ and R₂ are :

GATE ECE 2022 Network Theory - Sinusoidal Steady State Response Question 1 English

R₁ = 2 k$$\Omega$$, R₂ = 3 k$$\Omega$$

R₁ = 5 k$$\Omega$$, R₂ = 2 k$$\Omega$$

R₁ = 5 k$$\Omega$$, R₂ = 2.5 k$$\Omega$$

R₁ = 2 k$$\Omega$$, R₂ = 5 k$$\Omega$$

GATE ECE 2022

MCQ (Single Correct Answer)

-0.33

Consider the circuit shown in the figure with input V(t) in volts. The sinusoidal steady state current I(t) flowing through the circuit is shown graphically (where t is in seconds). The circuit element Z can be _________.

GATE ECE 2022 Network Theory - Sinusoidal Steady State Response Question 2 English

a capacitor of 1 F

an inductor of 1 H

a capacitor of $$\sqrt 3 $$F

an inductor of $$\sqrt 3 $$H

GATE ECE 2017 Set 1

Numerical

-0

In the circuit shown, the positive angular frequency $$\omega$$ (in radians per second) at which magnitude of the phase difference between the voltages $$V_1$$ and $$V_2$$ equals $$\frac{\mathrm\pi}4$$ radians, is __________. GATE ECE 2017 Set 1 Network Theory - Sinusoidal Steady State Response Question 59 English

GATE ECE 2017 Set 1 Network Theory - Sinusoidal Steady State Response Question 59 English

Your input ____

GATE ECE 2017 Set 2

Numerical

-0

In the circuit shown, $$V$$ is a sinusoidal voltage source. The current $$I$$ is in phase with voltage $$V$$. The ratio $${{{\rm{Amplitude of voltage across the capacitor }}} \over {{\rm{Amplitude of voltage across the resistor }}}}$$ is ______. GATE ECE 2017 Set 2 Network Theory - Sinusoidal Steady State Response Question 32 English