A particle of mass m is thrown horizontally from point P , as shown in the figure, with speed `5 m//s`. It strikes an inclined plane perpendicularly as shown. The inclination of the plane is `30^(@)` with the horizontal. Then, the height h shown in the figure is ( Take `g = 10 m//s^(2)` ) .

A ball is thrown at a speed of 20 m/s at an angle of 30 ^@ with the horizontal . The maximum height reached by the ball is (Use g=10 m//s^2 )

Determine the horizontal velocity v_0 with which a stone must be projected horizontally from a point P, so that it may hit the inclined plane perpendicularly. The inclination of the plane with the horizontal is theta and point P is at a height h above the foot of the incline, as shown in the figure.

A ball is thrown horizontally from a point O with speed 20 m/s as shown. Ball strikes the incline along normal after two seconds The speed of ball just before striking the plane is:

A ball is projected horizontally from an inclined plane with a velocity V, as shown in the figure. It will strike the plane after a time

A ball is thrown horizontally from a point O with speed 20 m/s as shown. Ball strikes the incline along normal after two seconds The displacement of ball in two seconds will be:

A projectile si thrown with velocity of 50m//s towards an inclined plane from ground such that is strikes the inclined plane perpendiclularly. The angle of projection of the projectile is 53^(@) with the horizontal and the inclined plane is inclined at an angle of 45^(@) to the horizonta.. (a) Find the time of flight. (b) Find the distance between the point of projection and the foot of inclined plane.

A particle of mass m is doing horizontal circular motion with the help of a string (conical pendulum) as shown in the figure. If speed of the particle is constant then,

A partile is projected up an incline (inclination angle = 30^(@) ) with 15sqrt(3) m//s at an angle of 30^(@) with the incline (as shown in figure) (g = 10 m//s^(2))

A particle of mass m is given initial horizontal velocity of magnitude u as shown in the figure. It transfers to the fixed inclined plane without a jump, that is, its trajectory changes sharply from the horizontal line to the inclined line. All the surfaces are smooth adn 90^(@) ge theta gt 0^(@) . Then the height to which the particle shamm rise on the inclined plane (assume the length of the inclined plane to be very large)

A particle of mass m is given initial horizontal velocity of magnitude u as shown in the figure. It transfers to the fixed inclined plane without a jump, that is, its trajectory changes sharply from the horizontal line to the inclined line. All the surfaces are smooth and 90^(@) ge theta gt 0^(@) . Then the height to which the particle shall rise on the inclined plane (assume the length of the inclined plane to be very large)