The variation of induced emf (`epsilon` ) with time (t) in a coil if a short bar magnet is moved along its axis with a constant velocity is best represented as

The variation of induced emf (E) with time (t) in a coil if a short bar magnet is moved along its axis with a constant velocity is best represent as

The variation of induced emf (E) with time (t) in a coil if a short bar magnet is moved along its axis with a constant velocity is best represent as

The variation of induced emf (E) with time (t) in a coil if a short bar magnet is moved along its axis with a constant velocity is best represent as

A cylindrical bar magnet is kept along the axis of a circular coil. If the magnent is rotated about its axis, then

STATEMENT -1 : The force acting on a particle moving alongx -axis is F = - alpha ( x+ vt) , where alpha is a constant. and STATEMENT-2 : To an observer moving along x-axis with constant velocity v, it represents SHM.

The velocity (v) - time (t) graph for a particle moving along x - axis is shown in the figure. The corresponding position (x) - time (t) is best represented by

For a body moving with uniform acceleration along straight line, the variation of its velocity (v) with position (x) is best represented by

A deflection magnetometer is placed with its arm along the east-west direction (tan A position) and a short bar magnet is placed symmetrically along its axis at some distance with its north pole pointing towards east. In this position the needle of the magnetometer shows a deflection of 60^(@) . If we double the distance of the bar magnet, then the deflection will be

A semi-circular loop of radius R is placed in a uniform magnetic field as shown. It is pulled with a constant velocity. The induced emf in the loop is

Two straight conducting rails form a right angle where their ends are joined. A conducting bar in contact with the rails starts at the vertex at time t = 0 and moves with constant velocity v along them as shown in Fig. A magnetic field vec(B) is directed into the page. the induced emf in the circuit at any time t is proportional to