A capacitor of capacitance 2 µF and resistor of resistance 12 Ω are connected in series with voltage source `V = (195 sqrt 2 )[sin(100 (rad) / s)t]` - The average power dissipated in the circuit will be

An inductor of reactance X_L = 4 Ω and resistor of resistance R = 3 Ω are connected in series with a voltage source of emf ε = (20 V)[sin (100pi ((rad)/s))t] . The current in the circuit at any time t will be

One 2 ohm resistor is connected in series with an inductor of reactance 1 Omega to a 5 V (rms ) A C source . Find the average power dissipated in the circuit .

In an alternating series circuit,current is i=100sin(100t)A and voltage is V=100sin(100t+π/6)v .The average power dissipated in the ac circuit is

An inductor of reactance 2 Omega and a resistor of 4 Omega are connected in series to the terminals of a 12 V (rms ) AC source. The power dissipated in the circuit is

A inductor of reactance 1 Omega and a resistor of 2 Omega are connected in series to the terminals of a 6 V (rms) a.c. source. The power dissipated in the circuit is

A resistor 20Omega , inductive reactance 15Omega and capacitive reactance 15Omega are connected in series to an AC voltage source V=200sqrt(2)sin omega t . Then the maximum current in the circuit is

An inductor 20xx10^(-3) a capacitor 100(mu)F and a resistor 50 Omega are connected in series across a source of emf V=10 sin 314 t . Then the energy dissipated in the circuit in 20 mim is

A choke coil is connected to an AC source. Some power is dissipated in coil. Now a capacitor is connected in series with the coil and source is same, then average power dissipated in the circuit does not changes. If ratio of inductive reactance of coil and capacitive reactance of capacitor is 1/x then find x