Orbiting Billiard Balls
At what angle must the billiard ball be struck for it to return to its start position?
Your answer will depend on the length and breadth of the table, but does it depend on where the ball is to start with?
Don't be too quick to accept this diagram - what assumptions might it be useful to make about the rebound angles?
Now use that to draw your own diagram.
Choose some dimensions to try for the table.
Draw a rectangle on paper to represent each table, and try out some angles.
We received solutions suggesting a number of ways to tackle this problem.
Jaime suggests a trial-and-error approach to help initially:
Drawing out the table(s) and experimenting with different paths (angles) will generate a 'feel' for the problem and begin to suggest some features and underlying relationships.
As Shaun observes,
One must assume the angle of incidence to be equal to the angle of reflection.He goes on to suggest constructing a right angled triangle:
Let's call the length of the table $L$, the height $h$, and the angle $x$. We'll also call the total distance travelled by the ball $Z$.
Note how if we get all the straight lines that make up the ball's path, and join them end to end, we have a line of length $Z$, inclined at angle $x$ to the horizontal. Its horizontal component is $Z\cos x$, and its vertical component is $Z\sin x$.
Now, looking back at the table, we see the horizontal distance travelled is $2L$, and the vertical distance is $2h$.
So: $Z\cos x$ = $2L$
$Z\sin x$ = $2h$
$\tan x$ = $\frac{h}{L}$
$x$ = arctan $\frac{h}{L}$
The position of the ball need not be taken into account in this case.
Andrei visualised the problem by imagining that each time the ball bounced against an edge, the table was reflected:
I observe that each time a ball strikes a margin of the table it will be reflected with a reflection angle equal to the angle of incidence. Let the dimensions of the billiard table be a and b. At each collision, I reflect the whole table around its side where the ball strikes (as above), and the trajectory of the ball is a straight line.
He then considered the triangle created by this straight line and the sides of the table, concluding that in the final reflection, the relative position of the red point is the same as the initial one.
In this case, $\tan x = \frac{mb}{na}$, where m and n are natural numbers
Finally, Tarj formed equations connecting time, orientation of the ball, size of the table and velocity (v1, v2). He then equated these and solved for v1/v2 = tanx. Very neatly done!
This is a hard but hopefully interesting scenario.
Drawing out the table(s) and experimenting with different paths (angles) will generate a 'feel' for the problem and begin to suggest some features and underlying relationships.
Ideally the context is rich in possibilities for extension and fresh questions. For example are orbital paths possible where a rebound does not always take the ball on to the adjacent side but instead across to the opposite side, and if such paths exist, what is the connection between simple orbits and those where the cycle involves more than 4 rebounds?