If `L = 25 mH, C = 1 mF` and `R = 10Omega` then R.M.S current across source is

An a.c. voltage of (V = 100 sin omega t) volt is connected across the parallel combination of inductor and capacitor having ( X_L = 5 Omega) and (X_C = 10 Omega) then current supplied by source is (in ampere)

An a.c. source is connected across an LCR series circuit with L = 100 mH, C = 0.1muF and R = 50 Omega . The frequency of ac to make the power factor of the circuit, unity is

An LCR series circuit with L = 100 mH, C = 100 muF, R = 120 Omega is connected to an AC source of emf epsilon = (30 V) sin (100s^(-1))t . Find the impedane, the peak current and the resonant frequency of the circuit.

In an L C R circuit having L = 8 H, C = 0 5muF and R=100Omega in series, the resonance frequency in rad/s is

In the circuit diagram shown, R = 10 omega, L = 5 mH, E = 10 V and i = 1 A . The current is decreasing at the reate of 10^(3) A//S . Then (V_(A) - V_(B)) at this instant is :

In the circuit shown in fig. X_(C ) = 100 Omega,(X_L)=200 Omega and R=100 Omega . The effective current through the source is

Figure here, shows a series L-C-R circuit connected to a variable frequency 230 V source. L = 5.0H, C = 80 muF and r = 40 Omega (a) Determine the source frequency which drives the circuit in resonance. (b) Obtain the impedance of the circuit and the amplitude of current at the resonating frequency. (c) Determine the rms potential drops across the three elements of the circuit. show that the potential drop across the L-C combination is zero at the resonating frequency.

200 V ac source is fed to series LCR circuit having X_(L)=50 Omega, X_(C )=50 Omega and R = 25 Omega . Potential drop across the inductor is

An LCR circuit has L = 10 mH, R = 3 Omega and C = 1 mu F connected in series to a source of 15cos omega t .volt. Calculate the current ampliuted and the average power dissipated per cycle at a frequency 10% lower than the resonance frequency.

A series LCR circuit with L = 4.0 H, C = 100 mu F and R = 60 Omega is connected to a variable frequency 240 V source. Calculate (i) angular frequency of the source which drives the circuit in resonance, (ii) current at the resonating frequency, (iii) rms potential drop across the inductance at resonance.