The inductor arrangement of Fig. 30-53, with `L_(1)` = 50.0 mH, `L_(2)` = 80.0 mH, `L_(3)` = 20.0 mH, and `L_(4)` = 15.0 mH, is to be connected to a varying current source. What is the equivalent inductance of the arrangement?

An inductor of 30 mH is connected to a 220 V, 100 Hz ac source. The inductive reactance is

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

A coil of inductance L = 300 mH and resitance R = 140 m Omega is connected to a constant voltage source. How soon will the coil current reach eta = 50 % of the steady-state value ?

An inductor (L=2000mH) is connected to an AC source of peak current. What is the instantaneous voltage of the source when the current is at its peak value?

Energy required to establish a current of 4 A in a coil of self-inductance L=200 mH is

A 1.5 mH inductor in an LC circuit stores a maximum energy of 30 mu J . What is the maximum current in the circuit ?

Two inductors L_(1) and L_(2) are connected in parallel and a time varying current flows as shown. the ratio of current i-(1)//i_(2)

Let R=200 Omega , C= 15.0 muF , L=230 mH , f_d = 60.0 Hz, and E_m =36.0 V . (These parameters are those used in the earlier sample problems). (a) What is the current amplitude I ?

An inductor of inductance L = 400 mH and resistors of resistance R_(1) = 2Omega and R_(2) = 2Omega are connected to a battery of emf 12 V as shown in the figure. The internal resistance of the battery is negligible. The switch S is closed at t = 0 . The potential drop across L as a function of time is