In the case of a body freely falling from small height

For a freely falling body

Show that the sum of kinetic energy and potential energy (ie, total mechanical energy) is always conserved in the case of a freely falling body under gravity (with air resistance neglected from a height by finding it when (i) the body is at the top c) the body has fallen a distance in the body has reached the ground.

The apparent weight of a freely falling body is

Read the following statements and choose the correct answer. (a) For a freely falling body the average velocity is proportional to square root of height of fall. (b) For a freely falling body the displacements in successive equal time intervals are in the ratio 1:4:9:.... (c) For a vertically projected body the displacement during last second of time of flight changes with velocity of projection. (d) For a body projected from the top of the tower the displacement of the body is negative when the body crosses the point of projection

The velocity of a freely falling body changes as g^ph^q where g is acceleration due to gravity and h is the height. The values of p and q are

Statement-1: A block is immersed in a liquid inside a beaker which is falling freely buoyant force acting on block is zero. Statement-2: In case of freely falling liquid there is no pressure difference between any two points.

A body falls from a certain bhight. Two seconds later another body falls from the same height. How long after the beginning of motion of the first body is the distance between the bodies twice the distance at the moment the second body starts to fall ?

The distance moved by a freely falling body (startibg from rest) during st, 2nd, 3nd,……nth second of its motion are propotional to .

If the distance travelled by a freely falling body in the last second of its journey is equal to the distance travelled in the first 2s, the time of descent of the body is

A rubber ball falls from a height h and rebounds to a height h/2. A rubber ball of double the mass falling from the same height h rebounds to a height