A condenser of `250 mu F` is connected in parallel to a coil of inductance `0.16 mH` while its effective resistance is `20 Omega`. Determine the resonant frequency

A capacitor of 250 mu F is connected parallel with a inductor of 0.16mH. IF the effective resistance is 20 Omega then resonant frequency……. Hz.

A capacitor of capacitance 250 pF is connected in parallel with a choke coil having inductance of 1.6 xx 10^(-2) H and resistance 20 Omega . Calculate (a) the resonance frequency and (b) the circuit impedance at resonance.

A capacitor of capacitance 250 pF is connected in parallel with a choke coil having inductance of 1.6 xx 10^(-2) H and resistance 20 Omega . Calculate (a) the resonance frequency and (b) the circuit impedance at resonance.

An an circuit consists of an inductor of inductance 10 mH connected in parallel with a capacitor of capacity 50 pF. Determine the resonant frequency.

An A.C. circuit consists of inductor of inductance 125 mH connected in parallel with a capacitor of capacity 50 muF . Determine the resonant frequency.

An A.C. circuit consists of inductor of inductance 125mH connected in parallel with a capacitor of capacity 50muF . Determine the resonant frequency.

When two resistors are connected in series, their effective resistance is 80 Omega . When : they are connected in parallel, their effective resistance is 20 Omega . What are the values of the two resistances?

A coil of inductance 300mH and resistance 2 Omega. The current reaches half of its steady state value in

A condenser of capacity 20 mu F is first charged and then discharged through a 10mH inductance. Neglecting the resistance of the coil, the frequency of the resulting vibrations will be