Three capacitors of capacitances `2muF, 2muF and 4muF` are connected to a battery of 10V as shown in the figure. Calculate the effective capacitance of the circuit and charge on each capacitor.

Three capacitors of capacitances 2muF, 2muF and 4muF are connected across a battery of 10V as shown in the adjoining figure (g). Calculate the effective capacitance and charge on each capacitor.

Four capacitors of capacitances 2 muF and 1muF are connected across a battery of 10V as shown in the figure (q). Calculate the net capacitance of the combination and net charge across each capacitor.

Two capacitors of capacitances 4muF and another two of 5muF are connected as shown in the given figure (f). Calculate the effective capacitance across points A and B.

Two capacitors of capacitances 4muF and 5muF are connected across a battery of 12 volts as shown in the adjoining figure (i). Calculate the total charge drawn from the battery.

Five capacitors of capacitance 10muF each are connected with each other, as shown in figure. Calculate the total capacitance between the points A and C.

Two capacitors of capacitances 4muF and 6muF are connected in series with a battery of 20 V. find the energy supplied by the battery.

Three capacitors each of capacitance C = 2muF are connected with a battery of emf 30 V as shown in the figure . When the switch S is closed , the heat generated in the circuit will be

Three capacitors of capacitances 3 muF , 6muF , and 4 muF are connected as shown across a battery of emg 6 V . . i. Find the equivalent capacitance, ii. Find the potential difference and charge on each capacitor. iii. Find the energy stored in the system of capacitors and total energy stored in the system of capacitor.

A network of four capacitors each of 15 mu F four capacitors each of the muF capacitance is connected to a 500 V supply as shown in the figure . Determine (a) equivalent capacitance of the network and (b) charge on each capacitor .