A 1.0 mH inductance, a `10 muF` capacitance and a 5.0 ohm resistance are connected in series to an a.c. source. It is found that the inductor and the capacitor show equal reactances. The reactance should be nearest to

An inductance of 200/pi mG ,a capacitance of (10^-3)/pi F and a resistance of 10 Omega are connected in series with an a.c. source 220 V, 50 Hz. The phase angle of the circuit is

An inductance of (200/pi) mH, a capacitance of ((10^(-3))/(pi)) F and a resistance of 10 Omega are connected in series with an a.c source 220 V, 50 Hz.The phase angle of the circuit 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, the applied voltage is

A resistor of 200 Omega , an inductor of 25 mH and a capacitor of 15.0 mu F are connected in series to a 220 V, 50 Hz ac source. Calculate the current through the circuit. Also find the phase difference between the voltage across the source and the current.

A resistor and a capacitor are connected in series to a 50 Hz ac source . The voltage (rms ) acrooss the resistor and capacitor are 151 V and 160.3 V respectively Calculate the rms voltage of the source .Also find the capactive reactance adn impedance of the circuit , if the circuit is 0.755 A .

In an a.c. circuit, a resistance of R Omega is connected in series with an inductance L. If phase angle between voltage and current be 45^@ , the value of inductive reactance will be

A coil of resistance 100Omega , an inductor of 0.5 H and a capacitor of 15muF are connected in series with a 200V-50Hz AC source. Calculate the current in the circuit.

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