Consider a L-C oscillation circuit. Circuit elements has zero resistance. Initially at t=0 all the energy is stored in the form of electric field and plate-1 is having positive charge:

at time `t=t_(1)` plate-2 attains half of the maximum+ve change for the first time. Value of `t_(1)` is :

A simple LR circuit is connected to a battery at time t = 0 . The energy stored in the inductor reaches half its maximum value at time

The circuit is switched on at t=0 , Find the time when energy stored in inductor becomes 1/n tiimes of maximum energy stored in it:

The circuit is switched on at t=0 , Find the time when energy stored in inductor becomes 1/n tiimes of maximum energy stored in it:

The charge on a capacitor plate in a circuit, as a function of time, is shown in the figure. What is the value of current at t=4s ?

Let C be the capacitance of a capacitor discharging through a resistor R. Suppose t_1 is the time taken for the energy stored in the capacitor to reduce to half its initial value and t_2 is the time taken for the charge to reduce to one-fourth its initial value. Then the ratio t_1//t_2 will be

In the circuit diagram shown, initially there is no energy in the inductor and the capacitor, The switch is closed at t = 0 . Find the current I as a function of time if R=sqrt(L//C)

When some potential difference V is applied across a resistance R then the work by the electrical field on the charge q to flow through the circuit in time t will be

In the circuit in Fig. switch S_(1) was closed for a long time . At time t = 0 the switch is opened. Find the angular frequency of oscillation of the charge on the capacitor.

In the circuit shown, the switch has been in position 1 for a long time. Now the switch is shifted to position 2. If this instant is taken as t = 0, then at time t=(pi)/(2)

Consider the RL circuit in Fig. When the switch is closed in position 1 and opens in position 2 , electrical work must be performed on the inductor and on the resistor. The energy stored in the inductor is for the resistor energy appears as heat. a. What is the ratio of P_(L)//P_(R ) of the rate at which energy is stored in the inductor to the rate at which energy is dissipated in the resistor? b. Express the ratio P_(L)//P_(R ) as a function of time. c. If the time constant of circuit is t , what is the time at which P_(L) = P_(R ) ?