The equivalent capacity between A and B in the given circuit is `(C_(1) =4muF,C_(2)=12 muF,C_(3)=8muF , C_(4)=4muF,C_(5)=8muF)`

If the equivalent capacity between A and B in the circuit is 12 muF , the capacity C is

The charge deposited on 4muF capacitor in the given circuit is:

The effective capacitence in muF in between A and B will be

(i) Find the equivalent capacitance of the combination shown in the figure (a), when C_(1)=2.0 muF,C_(2)=4.0 muF and C_(3) = 3.0 muF (ii) The input terminals A and B in Fig. (a) are connected to a battery of 12 V. Find the potential and the charge of each capacitor.

In the figure given below, find the, (a) equivalent capacitance of the network between points A and B. Given: C_1 = C_5 = 4muF , C_2 = C_3 = C_4 = 2 muF (b) maximum charge supplied by the battery, and (c) total energy stored in the network

Find the time constant for the given RC circuits in correct order (in mus ) R_(1)=1Omega,R_(2)=2Omega,C_(1)=4muF,C_(2)=2muF

A potential of V = 3000 V is applied to a combination of four initially uncharged capacitors as shown in the figure. Capacitors A, B, C and D have capacitances C_(A)=6.0 muF,C_(B)=5.2 muF,C_(C)=1.5 muF and C_(D) = 3.8 muF , respectiely. If the battery is disconnected, then potential difference across capacitor B is (approximately)

The time constant for the given RC circuits in the correct order (in mus ). R_(1)=1Omega,R_(2)=2Omega,C_(1)=4muF,C_(2)=2muF

In capacitor bridge, a voltage V_0 is applied and the variable capacitor C_1 has been adjusted till voltmeter shown zero reading. If C_(1)=8.9 muF, C_(2)=18muF, C_(3)=4.8muF at balance point, then C_x is

In the circuit shown C_(1) = 15 mu F, C_(2) == 30 muF , C_(3) = 30 muF , C_(4) = 30 muF and C_(5) = 60 muF . At steady state, the potential difference between points P and Q is 50 V. Calculate the potential difference across capacitor with capacitance C_(5)