A `100Omega` resistance and a capacitor of `100Omega` reactance are connected in series across a 220 V source. When the capacitor is `50% charged, the peak value of the displacement current is

A 100 Omega resistance and a capacitor of 100 Omega reactance are connected in series across a 220 V source. When the capacitor is 50% charged, the peak value of the displacement current is

A 0.2 k Omega resistor and 15 mu F capacitor are connected in series to a 220 V, 50 Hz ac source. The impadance of the circuit is

A 0.21 H inductor and a 12 Omega resistance are connected in series to a 220 V, 50 Hz ac source. The current in the circuit is

Three bulbs of 40 W , 60 W and 100 W are connected in series with a 240 V source.

Two bulbs 60 W and 100 W designed for voltage 220 V are connected in series across 220 V source. The net power dissipated is

A 0.21 H inductor and a 12 Omega resistance are connected in series to a 220 V, 50 Hz ac source. the phase angle between the current and the source voltage is

A resistor and a capacitor are connected in series with an a.c. source. If the potential drop across the capacitor is 5 V and that across resistor is 12 V, applied voltage is

A resistor of 200 Omega and a capacitor of 15.0muF are connected in series to a 220V , 50Hz source. (a) Calculate the current in the circuit . (b) Calcutalte the voltage (rms) across the resistor and the inductor. Is the algebraic sum of these voltages more than the source voltage? If yes, resolve the paradox.

A capacitor of capacitance 100 muF and a coil of resistance 50 Omega and inductance 0.5 H are connected in series with a 110 V, 50 Hz AC source. Find the rms value of the current.

An inductor 20 mH , a capacitor 100muF and a resistor 50Omega are connected in series across a source of emf V=10sin314t . The power loss in the circuit is