Three uncharged capacitors of capacitance `C_1,C_2` and `C_3` are connected to one another as shown in figure. The potential at `O` will be

Three uncharged capacitors of capacitance C_(1)=1mu F, C_(2)=2mu F and C_(3)=3mu F are connected as shown in the figure. The potential of point A, B and D are 10 volt, 25 volt and 20 volt respectively. Determine the potential at point O.

A capacitance C is connected to two equal resistance as shown in the figure. Then

Three capacitors are connected as shown in the figure . The potential at point O is equal to

Three capacitors of capacitance C_(1)= 3mu f, C_(2)= 6mu f and C_(3)= 10mu f , are connected to a 10V battery as shown in Figure 3 below Calculate: Electrostatic potential energy stored in the system

Three capacitors of capacitance C_(1)= 3mu f, C_(2)= 6mu f and C_(3)= 10mu f , are connected to a 10V battery as shown in Figure 3 below Calculate: Equivalent capacitance

Two capacitors C_1 and C_2 of capacitances C/2 and C/4 are connected to a V volt battery, as shown in figure. The ratio of energy slored in capacitors C_1 and C_2 is

Three identical charged capacitors each of capacitance 5 mu F are connected as shown in figure. Potential difference across capacitor (3), long time after the swithces K_(1) and K_(2) are closed , is

Three capacitors C_(1), C_(2) and C_(3) are connected to a battery as shown in the figure . The three capacitors have equal capacitances. Which capacitor stores the most energy ?

Three uncharged capacitors A, B and C are connected as shown in the figure. The charge on capacitor B is , the steady state.

Three equal capacitors, each with capacitance C are connected as shown in figure. Then the equivalent capacitance between A and B is