Two bodies of masses `(m_(1))` and `(m_(2))` are droppded from heithts `h_(1)` and `h_(2)`, respectively. They reach the ground after time `t_(1)` and `t_(2)` and strike the ground with `v_(1)` and `v_(2)`, respectively Choose the correct relations from the following.

Two bodies of masses m _(1) and m _(2) fall from heights h _(1) and h _(2) respectively. The ratio of their velocities when the hit the ground is

Two bodies of masses m_1 and m_2 (m_1 = 2m_2) are dropped from a height. The ratio of time taken by them to reach the ground is ________.

Two bodies A (of mass 1 kg ) and B (of mass 3 kg ) are dropped from heights of 16 m and 25 m . Respectively. The ratio of the time taken to reach the ground is :

Two bodies A (of mass 1 kg ) and B (of mass 3kg ) are dropped from heights of 16m and 25m ,respectively What is the ratio of the times taken by them to reach the ground?

Two masses m and 2m are dropped from height h and 2h. On reaching the ground, which will have a greater kinetic energy and why ?

The area of hole (1) is A_(1) and of hole (2) is A_(2) . The velocity of efflux and range of liquid is v_(1), v_(2) and x_(1), x_(2) for holes (1) and (2) respectively. The time taken by liquid, jet to reach the ground from holes (1) and (2) are t_(1) and t_(2) respectively. Cross section of tank is very very large compared to size of holes. {:(,"Column-I",,"Column-II"),((A),v_(1):v_(2),(p),2 : 1),((B),x_(1) : x_(2),(q),1 : 2),((C),t_(1) : t_(2),(r),1 : 1),((D),"if"A_(1) : A_(2) = 2 : 1",then"v_(1) : v_(2) =,(s),4 : 1):}

Two cars of same mass are moving with velocities v_(1) and v_(2) respectively. If they are stopped by supplying same breaking power in time t_(1) and t_(2) respectively then (v_(1))/(v_(2)) is

A ball of mass m_(1) and another ball of mass m_(2) are dropped from equal height. If the time taken by the balls are t_(1) and t_(2) , respectively, then

Two bodies P and Q of masses m_(1) and m_(2) (m_(2) gt m_(1)) are moving with velocity v_(1) and v_(2) force exerted by P on Q during the collision is

A binary star system consists of two stars of masses M_(1) and M_(2) revolving in circular orbits of radii R_(1) and R_(2) respectively. If their respective time periods are T_(1) and T_(2) , then