The potential difference across a `150 mH` inductor as a function of time is shown in figure. Assume that the initial value of the current in the inductor is zero. What is the current when `t=2.0 ms`? and `t = 4.0 ms` ?

The potential difference across a 10H inductor as a function of time is shown in the figure. At t=0 current is zero. Then

The potential difference across a 2 H inductor as a function of time is shown in figure. At time t=0 , current is zero Current t = 2 second is

The potential difference across a 2-H inductor as a function of time is shown in Fig. At time t = 0, current is zero. Current at t = 1 s is

The potential difference across a 2-H inductor as a function of time is shown in Fig. At time t = 0, current is zero. The variation of current versus time is

The potential difference a 2 H inductor as a function of time is shown in figure. At time t = 0 , current is zero Current versus time graph across the inductor will be

The potential difference across a 2-H inductor as a function of time is shown in Fig. At time t = 0 , current is zero. Area under V_(L) - t graph gives

The potentiak difference across a 2H inductor as a function of time is shown in the figure. At time t=0, current is zero. Current versus time graph across the inductor will be

The potential difference across a 4 H inductor vary with time is as shown. The current is Zero at t = 0, Then the current at time t =2s

Two capacitors of capacitance C and 3C are charged to potential difference V_(0) and 2V_(0) respectively, and connected to an inductor of inductance L as shown in figure. Initially the current in the inductor is zero. Now, the switch S is closed. The maximum current in the indcutor is :