A particle is projected from the surface of the earth with a speed of `20 m* s^(-1)` at an angle `30^@` with the horizontal .
The time of flight of that particle is

A particle is projected from the surface of the earth with a speed of 20 m* s^(-1) at an angle 30^@ with the horizontal . The range of that particle is

A particle is projected from the surface of the earth with a speed of 20 m* s^(-1) at an angle 30^@ with the horizontal . The maximum height the particle can reach is

A projectile is fired from the surface of the earth with a velocity of 5m *s^(-1) and angle theta with the horizontal . Another projectile fired from another planet with a velocity of 3 m*s^(-1) at the same angle follows a trajectory which is identical with the trajectory of the projectile fired from the earth. The value of the acceleration due to gravity on the planet is (in m*s^(-2) ) (given g=9.8 m*s^(-2) )

A stone is thrown up from the earth's surface with an initial velocity of 28 m*s^(-1) , making and angle 30^@ with the horizontal. Find the maximum height attained and the range of the projectile motion of the stone.

A particle is projected from the ground with a kinetic energy E at an angle of 60^(@) with the horizontal. Its kinetic energy at the highest point of its motion will be

A particle is projected with a velocity u in a direction making an angle alpha with the horizontal . Deduce the equation for the path of the projected particle.

A particle is projected with an initial velocity u, making an angle theta with the horizontal. Find the equation of the trajectory of the particle at any instant after the projection. Find expressions for the maximum height gained by the particle and its horizontal range.

A body is projected with a velocity 20 m*s^(-1) , making an angle of 45^@ with the horizontal. Calculate the maximum height it can attain