A stone is projected horizontally with a velocity `9.8 ms ^(-1)` from a tower of height 100 m. Its velocity one second after projection is `(g = 9.8 ms ^(-2)).`

A body is projected horizontally with a velocity of 4 ms^(-1) from the top of a high tower. The velocity of the body after 0.7 is nearly (Take, g = 10 ms^(-2))

A stone is thrown horizontally with velocity g ms^(-1) from the top of a tower of height g metre. The velocity with which it hits the ground is ("in" ms^(-1))

A body is projected horizontally from the top of a tower of height 10m with a velocity 10m/s .Its velocity after 1 second is

A stone is projected from the ground with a velocity of 14 ms ^(-1). One second later it clears a wall 2m high. The angle of projection is (g = 10 ms ^(-2))

A particle is projected from a horizontal plane with a velocity of 8sqrt2 ms ^(-1) ms at an angle theta . At highest point its velocity is found to be 8 ms^(-1) Its range will be (g=10 ms^(-2))

A body is projected with a velocity 60 ms ^(-1) at 30^(@) to horizontal . Its initial velocity vector is

A stone projected vertically up with velocity v from the top of a tower reaches the ground with velocity 2 v The height of the tower

A body is projected horizontally from a height of 78.4 m with a velocity 10 ms^(-1) .Its velocity after 3 seconds is (g=10 m//s^(2)) (Take direction of projection as i and vertically upward direction as j )

A body rolled on ice with a velocity of 8 ms^(-1) comes to rest after travelling 4 m. Compute the coefficient of friction. Given g= 9.8 ms^(-2)