I proposed the idea of having the year 12 and 13 students find the answer only through calculation. The other math teacher and I both worked on our plan for a few days, trying to find the simplest method we could. We both started with the idea of the tetrahedron. I stayed with the 3-d shape, using different triangles to find a constant of proportionality by which I could enlarge the tetrahedron to contain the balls and then spin it to form a cone. The other teacher used a 2-d cross section, and worked from congruent angles to enlarge the triangle and spin it.
We both got different answers. I haven't yet gone through the solutions above in depth, but so far it's looking like I'm gonna win.
Depends on which tetrahedron...
The one having as vertices the centers of the 4 balls (dense packing
of 4 balls in 3D space), then put the composite 4 balls solid inside
a cone. That's what is required.
Or a tetrahedron *containing* the balls ?
> I stayed with the 3-d shape, ... I could enlarge the tetrahedron
> to contain the balls
But packing *in* a tetrahedron is different of packing in a cone !
> The other teacher used a 2-d cross section,
That's seems the right method.
> We both got different answers.
Not surprising, if you started from a tetrahedron containing the
balls and he started with tetrahedron from the centers.
> ... but so far it's looking like I'm gonna win.
Who awards the prize ?
However, I agree with Avni's results, with a different expression as
sqrt( (sqrt(3)+1) / (sqrt(3)-1) ) (Avni's) can also be written as
(sqrt(3)+1) / sqrt(2) (mine)
Regards.
Note [OT] :
Also note that Avni's post and Ontadian's reply didn't propagate on
Usenet. Still stucked inside Drexel.
Just seen them because I went at Drexel site by chance, and for some
other reason.
I read/post to that forum through Usenet and my ISP's NNTP server.
--
Philippe Ch., mail : chephi...@free.fr
site : http://mathafou.free.fr/ (recreational mathematics)
Interesting problem, I used trigonometry to solve it, but we don't really need it, don't we? We only need to know some Tetrahedron properties like the height and the distance from the base center to one vertex, and from then on, it is only congruent triangles to play and achieve the solution.
I'm wondering, what is the maximum size a 5th ball can have, to be packed with the others in the same cone? How many can exist of the same size?