A capacitance `C`, a resistance `R` and an emf `E` are connected in series at `t=0` what is the maximum value of (a) the potential differnece across the resistor, (b) the current in the circuit , (c ) the power delivered by the battery. (d) the power converted into heat, (e) the potential differnece across the capicitor and (f) the energy stored in the capacitor.

Two capacitors of capacitances 20 .0pF and 50.0pF are connected in series with a 6.00V bettery . Find (a )the potential difference across each capacitor and (b) the energy stored in each capacitor .

A capacitor of capacitance 12(mu)F is connected to a battery of emf 6.00V and internal resistance 1.00(Omega) through resistanceless leads. 12.0(mu)s after the connections are made, what will be (a) the current in the circuit, (b)the power delivered by the battery ,(c)the power dissipated in heat and (d)the rate at which the energy stored in the capacitor is increasing.

an inductor of inductance 2.00 H is joined in series with a resistor of resistance 200 Omega and a battery of emf 2.00 V. At t = 10 ms, find (a) th current in the circuit, (b) the power delivered by the batter, (c ) the power dissipated in heating the resistor and (d) the rate at which energy is being stored in magnetic field.

In the circuit shown in figure find a. the equivalent capacitance b. the charge stored in each capacitor and c. the potential difference across each capacitor.

A capacitor and a resistor are connected in series with an a.c. source. If the potential difference across C, R are 120 V and 90 V repectively, and if rms value of current is 3 A, calculate impedance and power factor of the circuit.

An inductor of inducance 5.0 H, having a negligible resistance, is connected in series with a 100 Omega resistor and a battery of emf 2.0 V. Find the potential difference across the resistor 20 ms after the circuit is switched on.

The alternating emf of e=e_(0) sin omegat is applied across capacitor C. the current through the circuit is given by

If V_0 and I_0 are the peak current and voltge across the resistor in a series L-C-R circuit, then the power dissipated in the circuit is (power factor =costheta)