An alternating emf of 200V, 50Hz is applied to an L-R circuit, having a resistances R of `10Omega` and an inductance L of 0.05H connected in series. Calculate:
Impedance

An alternating emf of 200V, 50Hz is applied to an L-R circuit, having a resistances R of 10Omega and an inductance L of 0.05H connected in series. Calculate: Current flowing in the circuit

An alternating emf of 110 V is applied to a circuit containing a resistance R of 80 Omega and an inductor L in series. The current is found to lag behind the supply voltage by an angle theta=tan^(1) (3//4) . Find the : If the inductor has a coefficient of self inductance of 0.1 H, what is the frequency of the applied emf ?

An alternating emf of 110 V is applied to a circuit containing a resistance R of 80Omega and an inductor L in series. The current is found to lag behind the supply voltage by an angle theta=tan^(-1)(3//4) . Find the : (i) Inductive reactance (ii) Impedance of the circuit (iii) Current flowing in the circuit (iv) If the inductor has a coefficient of self inductance of 0.1 H. What is the frequency of the applied emf?

An alternating emf of 110 V is applied to a circuit containing a resistance R of 80 Omega and an inductor L in series. The current is found to lag behind the supply voltage by an angle theta=tan^^(1) (3//4) . Find the : Impedance of the circuit

An alternating emf of 110 V is applied to a circuit containing a resistance R of 80 Omega and an inductor L in series. The current is found to lag behind the supply voltage by an angle theta=tan^(1) (3//4) . Find the : Inductive reactance

The power factor of an AC circuit having resistance (R) and inductance (L) connected in series and an angular velocity omega is

An alternating e.m.f of 220V is applied to a circuit containing a resistor R having resistance of 160Omega and a capacitor .C. in series. The current is found to lead the supply voltage by an angle theta= tan^(-1) (3//4) Calculate: Impedance of the circuit

An alternating supply of 220 V is applied across a circuit with resistance 22 Omega and impedance 44 Omega . The power dissipated in the circuit is

An alternating e.m.f. of 200 V and 50 cycles is connected to a circuit of resistance 3.142 Omega) and inductance 0.01 H. The lag in time between the e.m.f. and the current is

A coil having a resistance of 5 Omega and an inductance of 0.02 H is arranged in parallel with another coil having a resistance of 1 Omega and an inductance of 0.08 H . Calculate the power absorbed when a voltage of 100 V at 50 Hz is applied. .