The circuit shown in figure is in the steady state with switch `S_(1)` closed. At t=0, `S_(1)` is opened and switch `S_(2)` is closed.

Find the first instant t, when energy in inductor becomes one third of that in capacitor

The circuit shown in figure is in the steady state with switch S_(1) closed.At t=0 , S_(1) is opened and switch S_(2) is closed. The first instant t when energy in inductor becomes one third of that in capacitor is equal to (pi xx 10^(-5))/x sec . Then finout value of x .

The circuit shows in Fig. is in the steady state with switch S_(1) closed. At t = 0,S_(1) is opened and switch S_(2) is closed. a. Derive expression for the charge on capacitor C_(2) as a function of time. b. Determine the first instant t , when the energy in the inductor becomes one-third of that in the capacitor.

Figure-5.150 shows LC circuit with initial charge on capacitor 200 mu C . If at t=0 switch is closed, find the first instant when energy stored in inductor becomes one third that of capacitor.

The circuit shown in the Figure is in steady state. Find the rate of change of current through L immediately after the switch S is closed.

A circuit containing capacitors C_1 and C_2 , shown in the figure is in the steady state with key K_1 and K_2 opened. At the instant t = 0 , K_1 is opened and K_2 is closed. (a) Find the angular frequency of oscillations of L- C circuit. (b) Determine the first instant t , when energy in the inductor becomes one third of that in the capacitor. (c) Calculate the charge on the plates of the capacitor at that instant.

A circuit containing two capacitor C_(1) and C_(2) shown in figure is in steady state with switch K_(1) closed and K_(2) open. At the instant t=0,K_(1) is opened and K_(2) is closed. The correct statements are.

At any time S_(1) switch is opened and S_(2) is closed then find out heat generated in circuit.

At t=0 , switch S is closed. Find time constant of the circuit and current through inductor as a function of time t .

In the circuit as shown in figure the switch is closed at t = 0 . At the instant of closing the switch