An indcutor having self inductance L with its coil resistance R is connected across a battery of emf `elipson`. When the circuit is in steady state t = 0, an iron rod is inserted into the inductor due to which its inductance becomes nL (ngt1).

When again circuit is in steady state, the current in it is

An indcutor having self inductance L with its coil resistance R is connected across a battery of emf elipson . When the circuit is in steady state t = 0, an iron rod is inserted into the inductor due to which its inductance becomes nL (ngt1). after insertion of rod, current in the circuit:

An indcutor having self inductance L with its coil resistance R is connected across a battery of emf elipson . When the circuit is in steady state t = 0, an iron rod is inserted into the inductor due to which its inductance becomes nL (ngt1). After insertion of rod which of the following quantities will change with time? (1) Potential difference across terminals A and B (2) Inductance (3) Rate of heat produced in coil

For resistances are connected by an ideal battery of emf 15 V, the circuit is in steady - state then the current (in ampere) in wire AB is :

An inductor of self-inductance L and resistor of resistance R are connected in series to a battery of emf E and negligible resistance.Calculate the maximum rate at which energy is stored in the inductor.

A coil having an inductance L and a resistance R is connected to a battery of emf E . Find the time taken for the magnetic energy stored in the circuit to change from one fourth of the steady-state value.

An inductor of inductance 10 mH and a resistance of 5 is connected to a battery of 20 V at t = 0. Find the ratio of current in circuit at t =  to current at t = 40 sec

A coil having inductance and L and resistance R is connected to a battery of emf in at t = 0 . If t_(1) and t_(2) are time for 90% and 99% completion of current growth in the circuit, then (t_(1))/(t_(2)) will be-