Consider the following diagram,
consider the following statements
(i) charge on `C_(1)`=charge on `C_(2)+` charge on `C_(3)`
(ii) `p.d`.across `C_(1)=p.d`.across `C_(2)+p.d`.across `C_(3)`
(iii) Energy stored in `C_(1)`=energy stored in `C_(2)+` Ebergy stored in `C_(3)`

The ratio of energy stored in capacitors C_(1) and C_(2)

Find the charge on capacitor C_(3) Given, then C_(1) = C_(2) and C_(3) = C_(4) = 3 C .

At t=0 switch S is closed . Find (a) charge on capacitor after one time constant (b) the time when p.d. across resistance equals p.d. across capacitance (c ) maximum energy stored in capacitor.

Consider . The charge appearing is C_(2) is.

Find currents I_(1),I_(2) and I_(3) and the energy stored in the capacitors C_(1) and C_(2) in the circuit shown in figure.

In the circuit shown in figure C_(1) =C_(2) = 2muF . Then charge stored in

In, the charges on C_(1),C_(2) , and C_(3) , are Q_(1), Q_(2) , and Q_(3) , respectively. .

In the circuit shown, C_(1) = C_(5) = C_(6) = 6.0 muF and C_(2) = C_(3) = C_(4) = 4.0 muF . What is the net charge stored on the capacitors and charge on C_(4) only ?

what is the charge stored on each capacitor C_1 and C_2 in the circuit shown in fig.

Capacitor C_(3) in the circuit is variable capacitor (its capacitance can be varied). Graph is plotted between potential difference V_(1) (across capacitor C_(1) ) versus C_(3) . Electric potential V_(1) approaches on asymptote of 10 volts as C_(3) to infty The ratio of energy stored in capacitor C_(1) to that of total energy when C_(3) toinfty is