An infinite no. of capacitors of capacities `C,4C,16C,64C,... ∞` are connected in series, their resultant capacitance will be-

Two capacitors with capacitances C_(1) and C_(2) are connected in series. Find the resultant capacitance.

Two capacitors with capacitances C_(1) and C_(2) are connected in parallel. Find the resultant capacitance.

Effective capacitance of parallel combination of two capacitors C_(1) and C_(2) is 10muF . When the capacitors are individually connected to a voltage source of 1V, the energy stored in the capacitor C_(2) is 4 times of C_(1) . If these capacitors are connected in series, their effective capacitor will be: lt

Three capacitors each of capacitance C are connected in series. Their equivalent capacitance is C_(s) . The same three capacitors are now connected in parallel. Their equivalent capacitance becomes C_(p) . Find the ratio ((C_(p))/(C_(s))) (Working must be shown).

There are 7 identical capacitors. The equivalent capacitance when they are connected in series is C. The equivalent capacitance when they are connected in parallel is

Three capacitor of capacitance C(mu F) are connected in parallel to which a capacitor of capacitance C is connected in series. Effective capacitance is 3.75. then capacity off each capacitor is

Two capacitors of capacitances C_(1)=2muF and C_(2)=8muF are connected in series and the resulting combination is connected across a 300V battery. Calculate the charge, potential difference and energy stored in the capacitor separately.

Six equal capacitors each of capacitance C are connected as shown in the figure. The equivalent capacitance between points A and B is

An LC series circuit has an oscillation frequency f. Two isolated inductors, each with inductance L and two capacitors each with capacitance C, all are connected in series and circuit is completed. The oscillation frequency is

An infinite ladder is constructed by connecting several sections of 2 mu F , 4 muF capacitor combination as shown in figure . It is terminated by a capacitor of capacitance C. What value should be chosen for C such that the equivalent capacitance of the ladder between points A and B becomes independent of the number of sections in between