1) Use the formula v^2 = u^2 + 2as (v = final velocity, u = initial velocity, a = acceleration, and s = displacement)
We want final velocity in the y direction to be 0, because this is the case when the ball stops in the air, at maximum height.
Therefore in the y-direction,
0 = 26^2 + 2*-9.8*s
Re-arrange to give,
s = -26^2/(2*-9.8) = 34.5 m.
2) First we need to know the time the cannonball was in the air. We do this by solving the following equation in the vertical direction:
v = u + at
We set v = 0, to find the time the ball stops in the air at maximum height. This will give us half the total time the ball is in the air.
0 = 26 + -9.8t
Re-arrange to give,
t = -26/-9.8 = 2.65 seconds
Therefore total air time = 2*2.65 = 5.3 seconds.
Now we need to calculate the horizontal distance covered in 5.3 seconds. We use the formula for the horizontal variables:
s = ut + 0.5*at^2
s = 38*5.3 [a = 0, because there is no acceleration in the horizontal direction]
s = 201.4 m
3)
Since there is no horizontal acceleration, horizontal speed = 38m/s for entire journey.
We need vertical acceleration after 2.7 seconds. We use this equation in the vertical direction:
v = u + at
v = 26 + -9.8*2.7
v = -0.46 m/s
Total velocity = sqrt(x-component^2 + y-component^2)
= sqrt(0.46^2 + 38^2) = 38m/s (approx)
4)
We use the equation:
s = ut + 0.5*at^2 [ for vertical direction ]
s = 26*2.7 + 0.5*-9.8*2.7^2
s = 34.48 m
