A body projected at `45^@` with a velocity of 20 m/s has a range of 10m. The decrease in range due to air resistance is `(g = 10ms^(-1))`

A particle of mass 2 kg is projected vertically upward with a velocity of 20 m/s. It attains maximum height of 17 m. The loss in mechanical energy due to air drag is ( g = 10 ms^-2)

A body is projected with a velocity of 30m/s to have to horizontal range of 45m. Find the angle of projection .

A particle is projected with velocity of 10m/s at an angle of 15° with horizontal.The horizontal range will be (g = 10m/s^2)

A body is projected with a velocity 60 ms^(-1) vertically upwards the distance travelled in last second of its motion is [g=10 ms^(-1)]

A body is projected horizontally from the top of a tower with a velocity of 30 m/s. The velocity of the body 4 seconds after projection is (g = 10ms^(-2) )

A particle is projected at an angle of 45^(@) with a velocity of 9.8 ms^(-1) . The horizontal range will be (Take, g = 9.8 ms^(-2))

A body is projected at angle 30° to horizontal with a velocity 50 ms^(-1) .In the above problem range of body is m. [g = 10 ms^(-2) ]

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 = 10ms^(-2) )

A body is project at t= 0 with a velocity 10 ms^-1 at an angle of 60 ^(@) with the horizontal .The radius of curvature of its trajectory at t=1s is R. Neglecting air resitance and taking acceleration due to gravity g= 10 ms^-2 , the value of R is :

A body projected with velocity 30 ms^(-1) reaches its maximum height in 1.5 s. Its range is (g= 10ms^(-2) )