In an inductor of inductance L = 100 mH, a current if l = 10 A is flowing. The energy stored in the inductor is

In an inductor of inductance L=100mH , a current of I=10A is flowing. The energy stored in the inductor is

In an inductor of inductance L=100mH , a current of I=10A is flowing. The energy stored in the inductor is

A current of 1 A through a coil of inductance of 200 mH is increasing at a rate of 0.5As^(-1) . The energy stored in the inductor per second is

In the figure shown the key is switched on at t=0 . Let l_1 and l_2 be the currents through inductors having self inductances L_1 and L_2 at any time t respectively. The magnetic energy stored in the inductors 1 and 2 be U_1 and U_2 . Then U_1/U_2 at any instant of time is:

In what form is the energy stored in an inductor or A coil of inductance L is carrying a steady current i . What is the nature of its stored energy

In an inductor of self-inductance L=2 mH, current changes with time according to relation i=t^(2)e^(-t) . At what time emf is zero ?

In an inductor of self-inductance L=2 mH, current changes with time according to relation i=t^(2)e^(-t) . At what time emf is zero ?

The cell in the circuit shows in Fig is ideal. The coil has an inductance of 4 mH and a resistance of 2 mOmega . The switch is closed at t = 0 . The amount of energy stored in the inductor at t = 2 s is (take e = 3)

The energy stored in an inductor of self inductance L carrying current l, is given by

The current through two inductors of self inductance 12 mH and 30 mH is increasing with time at the same rate. Draw graphs showing the variation of the (a ) e.m.f. induced with the rate of change of current in each inductor. (b) enargy stored in each inductor with the current flowing through it. Compare the energy stored in the coils if power dissipated in the coil is same.