From an inclined plane a particleis thrown in a direction normal to the surface. Find the ratio of successive ranges of the particle on inclined plane. Consider all collisions as elastic collisions (particle rebounds with the same speed with which it strikes the plane)

The ratio of the range of the particle and its maximum range in the inclined plane is:

A particle is projected on an inclined plane with a speed u as shown in (Fig. 5.61). Find the range of the particle on the inclined plane. .

A partacle is thrown in horizontal direction with speed u from a point P, the top of a tower shown in figure.1.49 at a vertical height h above the inclined plane of inclination theta . Find the speed with which the particle is thrown so that it strikes the plane normally. Also find the distance from the foot of the tower where the particle will strike.

A particle of mass m strikes another particle of same at rest. Find the angle between velocities of particles after the collision , if the collision is elastic.

A particle of mass m_(1) moving on a smooth surface with some velocity strikes another particle of mass m_(2) at rest. The head - on elastic collision takes place. After the collision , particles move with equal speed in opposite direction . Determine the mass ratio.

A particle is projected up an inclined plane of inclination beta at an elevation prop to nthe horizontal. Find the ratio between tan prop and tan beta , if the particle strikes the plane horizontally.

A particle is projected with velocity "u" in horizontal direction as shown in the figure. Find u if particle collides perpendicularly with inclined plane. h

A particle is projected with velocity "u" in horizontal direction as shown in the figure. Find u if particle collides perpendicularly with inclined plane. u

Two particles P and Q are projected from two points in the same plane as shown. Find the condition for collision of two paricles.