A series combination of `N_(1)` capacitors (each of capacity `C_(1)`) is charged to potential difference 3V. Another parallel combination of `N_(2)` capacitors (each of capacity `C_(2)`) is charged to potential difference V. The total energy stored in both the combinations is same, The value of `C_(1)` in terms of `C_(2)` is

A series combination of n_(1) capacitors, each of value C_(1) , is charged by a source of potential difference 4 V . When another parallel combination of n_(2) capacitors, each of value C_(2) , is charged by a source of potential difference V , it has same (total) energy stored in it, as the first combination has. the value of C_(2) , in terms of C_(1) , is then

A series combination of 5 capacitors, each of capacitance 1 mu F ,is charged by a source of potential difference 2V. When another parallel combination of 10 capacitors each of capacitance C_(2) ,is charged by a source of potential difference V ,it has the same total energy stored in it as the first combination has.The value of C_(2) is

A capacitor of capacitance C is charged to a potential difference V_(0) . The charged battery is disconnected and the capacitor is connected to a capacitor of unknown capacitance C_(x) . The potential difference across the combination is V. The value of C_(x) should be

A capacitor or capacitance C_(1) is charge to a potential V and then connected in parallel to an uncharged capacitor of capacitance C_(2) . The fianl potential difference across each capacitor will be

Sketch a graph to show how charge Q given to a capacitor of capacity C varies with the potential difference V.

A capacitor of capacity C_(1) is charged to the potential of V_(0) . On disconnecting with the battery, it is connected with a capacitor of capacity C_(2) as shown in the adjoining figure. The ratio of energies before and after the connection of switch S will be

A capacity of capacity C_(1) is charged up to V volt and then connected to an uncharged capacitor of capacity C_(2) . Then final potential difference across each will be

Find the ratio of potential difference that must be applied across the parallel and series combination of two capacitors C_(1) and C_(2) with their capacitance in the ratio 1:3 so that energy stored in the two cases becomes the same.

n capacitors each of capacity C are joined in parallel. If they are connected to a source of V volts, then the energy stored in the capacitor is