A rectangular loop is being pulled at a constant speed `v`, through a region of certain thickness `d`, in which a uniform magnetic field `B` is set up. The graph between position `x` of the right hand edge of the loop and the induced e.m.f. `E` will be

A square loop of edge a has N turns and a total resistance R . The loop moves with constant velocity v through a region of constant magnetic field B . The loop enters in magnetic field at t=0 . Discuss the vartion of (a) Flux passing through the loop (b) the induced emf and (c) the external force acting on the loop a function of position of the loop in the field.

An equilateral triangular loop ADC having some resistance is pulled with a constant velocity v out of a uniform magnetic field directed inot the paper. At time t = 0 , side DC of the loop at is at edge of the magnetic field. The induced current (i) versus time (t) graph will be as

The endpoints of a conducting string (shaped as a circular loop) of constant length are being pulled at a constant velocity v as shown in the figure. There exists a uniform magnetic field B is space which is perpendicular to the circular loop. If the loop always remains circular during the motion of its endpoints, them the emf induced in the loop at t=(piR)/(2v) is

A glass rod of length l moves with velocity in a uniform magnetic field B. What is the e.m.f. induced in the rod ?

A rectangular loop of length l and breadth b is situated in a uniform magnetic field of induction B with its plane perpendicular to the field as shown in the figure . Calculate the rate of change of magnetic flux and the induced emf if the loop is rotated with constant angular velocity omega (a) about an axis passing through the centre and perpendicular to the loop. (b) about an axis passing through the centre parallel to the breadth through angle 180^(@) .

A circular loop of radius r moves with a constant velocity v in a region with uniform magnetic field B . Calculate the potential difference between two points (A, B) , (C, D) , and (E, F) located on the loop.

A conducting loop is pulled with a constant velocity towards a region of uniform magnetic field as shown in the figure then the current involved in the loop is ( d gt r ) -

As loop of magnetic moment M is placed in the orientation of unstable equilbirum position in a uniform magnetic field B . The external work done in rotating it through an angle theta is

A rectangular loop of dimensions l & w and resistance R moves with constant velocity V to the right as shown in the figure. It continues to move with same speed through a region containing a uniform magnetic field B directed into the plane of the paper & extending a distance 3W . Sketch the flux, induced emf & external force acting on the loop as a function of the distance.