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.

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:

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:

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?

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 resulting curve?

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

Consider the RL circuit in Fig. When the switch is closed in position 1 and opens in position 2 , electrical work must be performed on the inductor and on the resistor. The energy stored in the inductor is for the resistor energy appears as heat. a. What is the ratio of P_(L)//P_(R ) of the rate at which energy is stored in the inductor to the rate at which energy is dissipated in the resistor? b. Express the ratio P_(L)//P_(R ) as a function of time. c. If the time constant of circuit is t , what is the time at which P_(L) = P_(R ) ?

Consider the RL circuit in Fig. When the switch is closed in position 1 and opens in position 2 , electrical work must be performed on the inductor and on the resistor. The energy stored in the inductor is for the resistor energy appears as heat. a. What is the ratio of P_(L)//P_(R ) of the rate at which energy is stored in the inductor to the rate at which energy is dissipated in the resistor? b. Express the ratio P_(L)//P_(R ) as a function of time. c. If the time constant of circuit is t , what is the time at which P_(L) = P_(R ) ?