The energy stored in the capacitor in the steady state is

Figure shows a network of capacitor and resistances. . 3V Potentials of some of the points are given. The energy (U) stored in the capacitor at steady state and the heat (H) dissipated in 1Omega resistor at steady state are

In the circuit as shown in figure, energy stored in capacitor at steady state is

In the circuit shown in figure 3.141, find the energy stored in 4muF capacitor in steady state.

The energy stored in 4 muF capacitors is

In the given circuit. E_(1) = 6 volts, E_(2) = 2 volts, E_(3) = 6 volts R_(1) = 6OmegaR_( 2)=2Omega R_(3) = 4Oemga, R_(4) = 3Omega and C=5muF . Find the current in R_(3) and energy stored in the capacitor at steady state

The charge on the 4muF capacitor in the steady state is

An uncharged capacitor C , Resistances R_(1)=R and R_(2)=2R , cells of emf epsilon_(1)=epsilon and epsilon_(2)=epsilon are connected as shown in the figure. Switch S is initially connected to terminal 1 for a long time and then it is connected to terminal 2 for an another long duration. IF H_(1) , U_(1) are the heat energies lost through the resistor R_(1) and energy stored in the capacitor respectively at steady state, when the switch is connected to terminal 1 and H_(2) , U_(2) are corresponding value when the switch is connected to terminal 2 . Choose the correct statements(s).

Find the total energy stored in the capacitors in the given network.

A battery of 10V is connected to a capacitor of capacity 0. lF . The battery is now removed and this capacitor is connected to a second uncharged capacitor. If the charges are distributed equally on these two capacitors, find the total energy stored in the two capacitors. Find the ratio of final energy to initial energy stored in capacitors.

Figure shows a part of network of a capacitor and resistors. The potential indicated at A, B and C are with respect to the ground. The charge on the capacitor on the capacitor in steady state is