Rate of increment of energy in an inductor with time in series RL circuit getting charged with battery of EMF Eis best represented by:

What is the maximum rate at which energy is stored in inductor (L) when it is connected in series with resistance R and one battery of emf E and negligible internal resistance? Refer to growth and decay of current in a coil, explained in competition file.

When a battery is connected across a series combination of self inductance L and resistance R , the variation in the current i with time t is best represented by

As shown in the figure, a battery of emf is connected to an inductor L and resistance R in series. The switch is closed at . The total charge that flows from the battery, between t=t_e and t=2t_e ( t_e is the time constant of the circuit) is:

A constant current exists in an inductor coil connected to a battery. The coil is short circuited and the battery is removed. Show that the charge flown through the coil aftter the short circuiting is the same as that which flows in one time constant before the short circuiting.

In an LR circuit connected to a battery, the rate at which energy is stored in the inductor is plotted against time during the growth of current in the circuit. Which of the following best represents the resulation curve?

At t = 0, a battery is connected to a series arrangement of a resistor and an inductor. At what multiple of the inductive time constant will the energy stored in the inductor's magnetic field be 0.500 of its steady-state value?

Consider a circuit consists of resistors, inductor, battery and a switch as shown. Resistance of resistors, inductance of inductor and EMF of battery are indicated. The switch is closed at t=0 . Find time constant of LR circuit during growth of current