In the figure shown `AB` is a plastic rod moving with a constant velocity `v`, `W` is an infinite long wire carrying current `I`. The end of the rod which is at higher potential is

A conducting circular loop of radius a and resistance per unit length R is moving with a constant velocity v_0 , parallel to an infinite conducting wire carrying current i_0 . A conducting rod of length 2a is approaching the centre of the loop with a constant velocity v_0/2 along the direction 2 of the current. At the instant t = 0 , the rod comes in contact with the loop at A and starts sliding on the loop with the constant velocity. Neglecting the resistance of the rod and the self-inductance of the circuit, find the following when the rod slides on the loop. (a) The current through the rod when it is at a distance of (a/2) from the point A of the loop. (b) Force required to maintain the velocity of the rod at that instant.

A rod of length l is rotating with an angular speed omega about its one end which is at a distance a from an infinitely long wire carrying current i .Find the emf induced in the rod at the instant shown in the figure.

A rod of length l is rotating with an angular speed omega about one of its ends which is at a distance a from an infinitely long wire carrying current i . Find the emf induecd in the rod at the instanr shown in .

A copper rod moves with a constant angular velocity omega about a long straight wire carrying a current I. If the ends of the rod from the wire are at distances a and b, then the e.m.f induced in the rod is

A cionducing rod moves with constant velocity v perpendicular to the straight wire carrying a current I as shown compute that the emf generated between the ends of the rod

A rod of length l is rotating with an angular speed omega about one of its ends which is at a distance a from an infinitely lonf wire carrying current i . Find the emf induced in the rod at the instant shown in .

A uniform metal rod is moving with a uniform velocity v parallel to a long straight wire carrying a current I. The rod is perpendicular to the wire with its ends at distance r_(1) and r_(2) (with r_(2) gt r_(1) ) form it. The E.M.F. induced in the rod at that instant is

Two perpendicular infinite wires are carrying current i as shown in the figure. The magnetic field at point P is :

A rod AB moves with a uniform velocity v in a uniform magnetic field as shown in figure.

a rectangular loop, as shown in Fig. 3.66, moves away from an infinitely long wire carrying a current I. Find the emf induced in the rectangualr loop.