List of top Electrical Circuits Questions

The circuit shown in the figure functions as which one of the following digital circuit blocks ?
Digital Circuit Block
A series RLC circuit is connected to 220 V, 50 Hz supply. For a fixed value of R and C, the inductor \(L\) is varied to deliver the maximum current. This value is 0.4 A and the corresponding potential drop across the capacitor is 330 V. The value of the inductor \(L\) is ______ H (rounded off to two decimal places).
The linear temperature coefficient of the material of a wire is \(x \times 10^{-4} \, \text{°C}^{-1}\). The resistance of this wire increased from 50 \(\Omega\) at 25 °C to 60 \(\Omega\) at 75 °C. The value of \(x\) is ________ (rounded off to two decimal places).
A series RLC circuit with \(R=10\,\Omega\), \(L=50\text{ mH}\), \(C=100\ \mu\text{F}\) connected to \(200\ \text{V}\), \(50\ \text{Hz}\) supply consumes power \(P\). The value of \(L\) is changed such that the circuit consumes the same power but operates with lagging power factor. The new value of \(L\) is _____ mH (rounded off to two decimal places).
Power consumed by the \(3\,\Omega\) resistor is \(12\ \text{W}\) in the given circuit. The value of the resistor \(R\) in the circuit is _______ \(\Omega\).

In the circuit given below, \(V_s = 50\ \text{V}\). Let the circuit reach steady state for the SPDT switch at position 1. Once the circuit is switched to position 2, the energy dissipated in the resistors is \(\underline{\hspace{1cm}}\) J (rounded off to one decimal place). 

In the circuit shown below, \( R_1 = 2 \, \Omega \), \( R_2 = 1 \, \Omega \), \( L_1 = 2 \, H \), and \( L_2 = 0.5 \, H \). Which of the following describe(s) the characteristics of the circuit? 

In the circuit shown below, $V_5 = 100 V$, $R_1 = 30 \Omega$, $R_2 = 60 \Omega$, $R_3 = 90 \Omega$, $R_4 = 45 \Omega$, and $R_5 = 30 \Omega$. The current flowing through resistor $R_3$ is \(\underline{\hspace{1cm}}\) A. (rounded off to two decimal places)

An ideal inductor with an inductance value of 1/3 H is connected to a 50 Hz sinusoidal AC voltage source. The energy stored in the inductor is 6 J. The value of the maximum power delivered to the inductor is \(\underline{\hspace{1cm}}\) W.

Three resistive loads are connected to ideal voltage and current sources as shown in the circuit below. The voltage $V_{AB}$ across the terminals A and B is equal to \(\underline{\hspace{1cm}}\) V.