An inductor (L = 100 mH), a resistor `(R = 100Omega)` and a battery (E = 100 V) are initially connected in series as shown in the figure. After a long time the battery is disconnected after short circuiting the points A and B. The current in the circuit 1 ms after the short circuit is

An inductor (L=100 mH) , a resistor (R=100 ohm) and a battery (E=100 V) are. initially connected in series as shown in the figure. Afler a long time, the battery is disconnected after short-circuiting the points A and B . The current in the circuit, 1 ms after the short-circuit, is (k)/(4) . Find k . '(##CEN_KSR_PHY_JEE_CO23_E01_027_Q07##)'

An inductor (L =20 mH) , a resistor ( R = 100 Omega) and a battery (verepsilon = 10 V) are connected in series. After along time the circuit is short- circuited and then the battery is disconnected. Find the current in the cirucit 1ms after short- circuititig.

A inductor of 20mH inductance and a resistor of 100 Omega resistance are connected in series to a battery of emf 10V. After a long time the circuit is short-circuited and the battery is disconnected. Find the current in the circuit 1 ms after short-circuiting.

Battery is connected to a resistor and a inductor for a long time as shown in figure then battery is removed and short circuited. Find the current in the circuit after 1ms after battery get removed.

An inductor (L = 20 mH) , a resistor (R = 100 Omega) and a battery (varepsilon = 10 V) are connected in series. Find (a) the time constant, (b) the maximum current and (c ) the time elapsed before the current reaches 99% of the maximum value.

An inductor (L =0.03 H) and a resistor (R = 0.15k(Omega)) are connected in series to a battery of 15 V EMF in a circuit shown below. The key K_(1) is opened and Key K_(2) is closed simultaneously. At t =1 ms, the current in the circuit will be (e^(5) = 150)

An inductor 20 mH , a capacitor 100 muF and a resistor 50 Omega are connected in series across a source of emf, V=10 sin 314 t . The power loss in the circuit is