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-

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 of inductance 1 H and resistance 10Omega is connected to a resistanceless battery of emf 50 V at time t=0 . Calculate the ratio of rthe rate which magnetic energy is stored in the coil to the rate at which energy is supplied by the battery at t=0.1s .

Two coil A and B have inductances 1.0 H and 2.0 H respectively. The resistance of each coil is 10 Omega . Each coil is connected to an ideal battery of emf 2.0 V at t = 0 Let i_A and i_B be the current in the two circuit at time t. Find the raito i_A/ I_B at (a) t=100ms, (b) t= 200 ms and (c ) t = 1 s.

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

Switch is closed at t = 0 then the current in the circuit at t = L/2R is

A coil with active resistance R and inductance L was connected at the moment t=0 to a source of voltage V=V_(m)cos omegat. Find the current in the coil as a function of time t .

An uncharged capacitor of capacitance C is connected with a battery of EMF V and a resistance R. The switch is closed at t=0 . The time instant at which the current in the circuit is (V)/(4R) is t=

A coil of wire having inductance and resistance has a conducting ring placed coaxially within it. The coil is connected to a battery at time t=0, so that a time-dependent current 1_(1)(t) starts following through the coil. If I_(2)(t) is the current induced in the ring, and B (t) is the magnetic field at the axis of the coil due to I_(1)(t) then as a function of time (tgt0) , the product I_(2)(t)B(t)