An ideal resistance R, ideal inductance L , ideal capacitance C and AC voltmeters `underset(1)(V)` , `underset(2)(V)` , `underset(3)(V)` and `underset(4)(V)` are connected to an AC source as shown . At resonance

A voltmeter connected in an A.C circuit reads 220 V . It represents,

For series L-C-R circuit shown in the figure, the readings of underset(1)(V) and underset(3)(V) are same and each equal to 100 V .Then

Two identical charged particles are projected simul- taneously from origin in xy plane. Each particle has charge q and mass m and has been projected with velocity v as shown in the figure. There exists a uniform magnetic field B in negative z direction. (i) Find underset(V)to_(1).underset(V)to_(2) at time t where underset(V)to_(1) and underset(V)to_(2) are velocities of the particles at time t. Find underset(V)to_(1).underset(V)to_(2) at time t=(pim)/(qB) where underset(r)to_(1).underset(V)to_(2) are the position vectors of the two particles.

In an AC circuit , underset(o)(V) , underset(o)(I) and cos theta are voltage amplitude , current amplitude and power factor respectively, the power consumption is

If resistance R =100 Omega, inductance L = 12mH and capacitance C=15muF are connected in series to an AC sources, then at resonance the impedance of circuit is

A resistance (R), inductance (L) and capacitance (C) are connected in series to an ac source of voltage V having variable frequency. Calculate the energy delivered by the source to the circuit during one period if the operating frequency is twice the resonance frequency.

An ideal inductor of inductance 50muH is connected to an AC source of 220V, 50 Hz. Find the inductive reactance.