The current-frequency response curves are shown in figures above for three LCR circuits.
a. What is Q-factor of the LCR circuit? b. Which of the curves in the above figures has highest Q value? C. Write an expression for the value. d. Can any of the curves shown in the figures represent current-frequency response of a parallel LCR circuit?

Find the value of current I in the circuit shown in figure.

Obtain the resonant frequency omega of a series LCR circuit with L = 2.0 H, C = 32muF and R = 10 Omega . What is the Q-value of this circuit ?

A part of a circuit in steady state along with the currents flowing in the branches,the values of resistances,etc, is shown in figure.Calculate the energy stored in the capacitor.

Each of the resistors shown in figure has a resistances of 10(Omega) and each of the batteries has an emf of 10V.Find the currents through the resistors a and b in the two circuits.

In the circuit shown in the figure , the input voltage V_i is 20 V, V_BE =0V and V_CE =0V. What are the value of I_B,I_C,beta ?

A series LCR circuit with L = 0.12 H, C = 480 nF, R = 23Omega is connected to a 230 V variable frequency supply. a. What is the source frequency for which current amplitude is maximum? Obtain this maximum value. b. What is the source frequency for which average power absorbed by the circuit is maximum? Obtain the value of this maximum power. c. For which frequencies of the source is the power transferred to the circuit half the power at resonant frequency? What is the current amplitude at these frequencies? d. What is the Q-factor of the given circuit?

A fascinating behaviour of the series RLC circuit is the phenomenon of resonance. a. Explain Resonance in an LCR circuit. b. Draw a graphical representation of variation of current amplitude in with frequency w. c. What do you mean by sharpness of resonance? Explain it.