(a) Explain what is meant by acceleration of free fall due to gravity, g.
(b) State two reasons why g varies on the surface of the earth
(c) A stone is projected upwards at an angle of 30° to the horizontal from the top of a tower of height 100 m and it hits the ground at a point Q. If the initial velocity of projection is 100ms(^{-1}), calculate the
(i) maximum height of the stone above the ground;
(ii) time it takes to reach this height;
(iii) time of flight
(iv) horizontal distance from the foot of the tower to the point Q. (Neglect air resistance and take g as 10m(^{-2}))
Explanation
(a) This is the force of attraction of the Earth on a mass
It is a vector quantity and is measured in ms(^{-2})
It pulls the acceleration when a body is in vacuum or without resistance. OR/F = g
(all symbols explained) where F = force of gravity, M = mass of the object
(b) — (Shape of the earth). The earth is not a perfect sphere (1) or the shape of the earth is elliptical – Rotation of the Earth about its polar axis.
(c)(i) Let H = height of tower and h = vertical difference covered by the stone from the point of projection.
(i) V(_2) = (Usin(theta))(^2) – 2gh
(theta) = 100 x 100 x ((frac{1}{2}))(^2) – 20h
h = (frac{2500}{20})
= 125m
height above the ground
(i) S = H + 125 S = 100 + 125 S = 225m
(ii) V = U sin (theta) – gt
0 = 100 sin 30° – 10t
t = (frac{100 times 0.5}{10})
t = 5s
(iii) Using S = ut + 1/2 gt(^2)
225 = 0 + 1/2 x 10t(^2)
t = (sqrt{45}) = 6.71
Time of flight, T= 5 + 6.
T = 11.71s
(iv) Range R = UTcos(theta)
Or S = ut – 1/2 gt(^2)
g = 0
=100 x 0.8660 x 11.71
= 1014.08 (C14)
Range (frac{U^2 sin20}{ g})
= 1013.22m