`ABCDE` is a smooth iron track in the vertical plane. The sections `ABC` and `CDE` are quarter circles. Points `B` and `D` are very close to `C.M` is a small magnet of mass `m`. The force of attraction between `M` and the track is `F`, which is constant and always normal to the track. `M` starts from rest at `A`, then:

In the given figure, a smooth parabolic wire track lies in the xy -plane (vertical). The shape of track is defined by the equation y=x^(2) . A ring of mass m which can slide freely on the wire track, is placed at the position A (1,1) . The track is rotated with constant angular speed omega such that there is no relative slipping between the ring and the track. The value of omega is

A small block of mass m slides along a smooth frictional track as shown in the figure. If it starts from rest at P, what is the resultant force acting on it at Q?

A small sphere rolls down without slipping from the top of a track in a vertical plane. The track has an elevated section and a horizontal part. The horizontall part is 1.0 meter above the ground level and the top of the track is 2.4 meter above the ground. Find the distance on the ground with respect to a point B ( which is vetically below the end A of the track as shown in fig.) where the sphere lands. . (A) 1 m (B) 2 m ( C) 3 m (D) 4 m .

A small sphere rolls down without slipping from the top of a track in a vertical plane. The track has an elevated section and a horizontal part, The horizontal part, is 1.0 metre above the ground lenvel and the top of the track is 2.4 meters above the ground. Find the distance on the ground with respect to the point B (which is vertically below the end of the track as shown i fig.) where the sphere lands. During its flight as a projectlie, does the sphere continue to rotate about its centre of mass? Explain.

A smooth track, fixed to the ground, is in the shape of a quarter of a circle. Two small blocks of mass 3m and 2m are released from the two edges A and B of the circular track. The masses slide down and collide at centre O of the track. Vertical height of A and B from O is h = 2m . Collision is elastic. Find the maximum height (above O) attained by the block of mass 2m after collision

A block of mass m is placed on a vertical fixed circular track and then it is given velocity v along the track at position A on track. The coefficient of friction between the block and the track varies with the angle theta . If the block moves on track with constant speed then the coefficient of friction is

A smooth semicircular wire track of radius R if fixed in a vertical plane. One end of massless spring of netural length (3R)/(4) is attached to the lowest point O of the wire track. A small ring of mass m which can slide on the track is attched to the other end of the spring. the ring is held stationary at point P such that the spring makes an angle of 60^(@) with the vertical. The spring constant is K = (mg)/(R ) . considering the instance when the ring is released, the free body diagram of the ring, when a_(T) is tengential acceleration, F is restoring force and N is normal reaction is

A smooth circular track of mass M is vertically hung by a string down the ceiling. Two small rings, each of mass m , are initially at rest at the top of the track. They then slide down simultaneously along the track in opposite directions. Find the position of the rings when the tension in the string is zero.

A block is freely sliding down from a vertical height 4 m on smooth inclined plane. The block reaches bottom of inclined plane and then it decribes vertical circle of radius 1 m along smooth track. The ratio of normal reactions on the block while it crossing lowest point and highest point of vertical circle is