The diagram given below shows a solenoid carrying time varying current `l= l_(0)t`. On the axis of the solenoid, a ring has been placed. The mutual inductance of the ring and the solenoid is M and the self inductance of the ring is L. If the resistance of the ring is R then maximum current which can flow through the ring is

The diagram shows a solenoid carrying time varying current I=I_0t ( I_0 is constant) on the axis of this solenoid a conducting ring is being placed as shown in the figure. The mutual inductance of the ring and the solenoid is M and self inductance of the ring is L . if the resistance of the ring is R then the maximum current which can flow through the ring is

A long straight wire is placed along the axis of a circuit ring of radius R. The mutual inductance of this system is

In an inductor, the current / varies with time to l = 5A + 16.(A//s)t . If-induced emf in the induct is 5 mV, the self inductance of the inductor is

A long solenoid has 1000 turns. When a current of 4A flows through it, the magnetic flux linked with each turn of the solenoid is 4xx10^(-3)Wb . The self-inductance of the solenoid is

A long solenoid has 1000 turns. When a current of 4A flows through it, the magnetic flux linked with each turn of the solenoid is 4xx10^(-3)Wb . The self-inductance of the solenoid is

A long solenoid has 1000 turns. When a current of 4A flows through it, the magnetic flux linked with each turn of the solenoid is 4xx10^(-3)Wb . The self-inductance of the solenoid is

When a battery is connected across a series combination of self inductance L and resistance R , the variation in the current i with time t is best represented by

A long solenoid of diameter 0.1 m has 2 xx 10^(4) turns per meter. At centre of the solenoid is 100 turns coil of radius 0.01 m placed with its axis coinciding with solenoid axis. The current in the solenoid reduce at a constant rate to 0A from 4 a in 0.05 s . If the resistance of the coil is 10 pi^(2) Omega , the total charge flowing through the coil during this time is

A long solenoid of radius R carries a time (t) – dependent current I=I_(0)(t-2t^(2)) A circular ring of radius = R is placed near the centre of the solenoid and plane of ring makes an angle 30^(@) with the axis of solenoid. The time at which magnetic flux through the ring is maximum is :

A long solenoid of radius R carries a time (t) – dependent current I=I_(0)(t-2t^(2)) A circular ring of radius = R is placed near the centre of the solenoid and plane of ring makes an angle 30^(@) with the axis of solenoid. The time at which magnetic flux through the ring is maximum is :