Question 731943
How does that man "project a ball upwards? How high is the top of the train at the place the ball could hit?
Whatever height the man shoots the ball from let's assume the ball would hit the train at that height or miss the train. Lets say the ball is shot up from the train floor and may fall on the floor of one of some open top cars near the back of the train or miss the train entirely.
 
THE TEACHER'S SOLUTION:
As the problem says "projects", students should apply
the formula for projectile motion learned in class to describe the ball motion,
and the formula for uniformly accelerated motion to describe the motion of the train.
For a projectile projected up from a height {{{h[0]}}} at an initial speed {{{v[0]}}} ,
under gravity with an acceleration {{{g}}}, the height as a function of time is
{{{h(t)=-gt^2/2+v[0]t+h[0]}}}
For distance {{{d}}} covered under uniformly accelerated motion during time {{{t}}} with initial speed {{{v[0]}}} with a constant acceleration {{{a}}} is
{{{d(t)=v[0]t+at^2/2}}}
The commonly used value for acceleration of gravity om Earth is
{{{g=9.8}}}{{{m/s^2}}}
With {{{h[0]=0}}}{{{m}}} and {{{v[0]=50}}}{{{m/s}}}, using meter and second units,
we have {{{h(t)=-4.9t^2+50t}}} for the ball.
Factoring it as {{{h(t)=(-4.9t+50)t}}} we se  that {{{h(t)=0}}} for
{{{t=0}}} and {{{t=50/4.9}}}={{{10.2}}} seconds for the ball.
For the train, with units of meters and seconds, we have {{{v[0]=0}}} and {{{a=6}}} ,
so we get the distance covered during while the ball is in the air as
{{{d(10.2)=0+6*10.2^2/2}}}={{{highlight(312.2)}}} meters.
That is less than the length of the train, so there is still part of the train under the ball as the ball gets down, and hits the train.
 
THE FIFTH GRADER'S SOLUTION: 
The ball starts with an upwards speed of 50meters/second(50m/s), and gravity makes that speed decrease at a rate of {{{9.8}}}{{{m/s^2"}}} until the upwards speed is zero.
After that the ball continues to accelerate downwards at {{{9.8m/s^2}}}  from the speed of {{{0m/s}}} it had at the top of its flight. If nothing stops the ball, it would reach the height level it started from, and at that point its downwards speed would be {{{50m/s}}}.
The speed change from 0m/s to 50m/s at a rate of {{{"9.8m/"}}}{{{s^2}}} should take
{{{((50m/s))/((9.8m/s^2))}}}{{{"="}}}{{{5.1s}}}
That is the time the ball spent going up to its greatest height.
From there, it would take the same time accelerating from {{{0m/s}}} to {{{50m/s}}} downwards to get to the height it started at the level of the train floor.
The round trip would have taken {{{5.1s+5.1s=10.2s}}} .
During that time the train has accelerated from {{{0m/s}}} at {{{6m/s^2}}} , and has reached a speed of
{{{(6m/s^2)*(10.2s)=61.2m/s}}} (rounded).
The distance the train covered during those 10.2 seconds, can be calculated as average speed times 10.2 seconds:
Because the acceleration was constant, the speed increased linearly and the average speed is the average of initial and final speeds for that period of time:
{{{0m/s+61.2m/s=30.6m/s}}} , and the distance covered during that time period was {{{(30.6m/s)*(10.2s)=highlight(312.2m)}}} (rounded).
That mean the front of the train moved that far and as the train's length is {{{340m>312.24m}}} ,
a spot in the train 312.24 meters behind the front of the train is now where the front of the train was when the ball was projected upwards. The ball will hit the train at that spot.