A man is slipping on a frictionless inclined plane and a bag falls down from the same height. Then the velocity of both is related as (`V_(B)=` velocity of bag and `V_(m)=` velocity of man)

A man is slipping on a frictions inclined plane & a bag falls down from the same height. Then the speed of both is related as:

A disc and a ring of the same mass are rolling down frictionless inclined plane, with the same kinetic energy. The ratio of the velocity of disc to the velocity of ring is

A man moving with a speed v down the inclined plane meets the rain horizontally with same speed. The actual velocity of rain is?

A ring rolls down an inclined plane and acquires a velocity v upon reaching the bottom of the inclined plane. If another body rolls down from the same height over the same inclined plane and acquires a velocity sqrtfrac{6}{5}v upon reaching the bottom of the inclined plane, then that body is

A solid cylinder rolls down from an inclined plane of height h. What is the velocity of the cylinder when it reaches at the bottom of the plane ?

A solid cylinder at rest at top of an inclined plane of height 2.7 m rolls down without slipping. If the same cylinder has to slide down a frictionless inclined plane and acquires the same velocity as that acquired by centre of mass of rolling cylinder at the bottom of the incline, what should be the height of inclined plane?

A ring starts to roll down the inclined plane of height h without slipping . The velocity when it reaches the ground is

The relation between wave velocity and maximum particle velocity is (Where V_(p) = Particle velocity, V = Wave velocity)

A solid sphere of mass M and radius R, rolling down a smooth inclined plane, without slipping, reaches the bottom with a velocity v. What is the height of the inclined plane in terms of the velocity v ?