| T.R | Title | User | Personal
Name | Date | Lines |
|---|
| 1475.1 | Tennis, anyone? | CIVAGE::LYNN | Lynn Yarbrough @WNP DTN 427-5663 | Thu Aug 01 1991 18:07 | 11 |
| The sphere packing problem is related to the following 2-dimensional
problems:
a) How many unit circles can be placed tangent to a given unit circle?
b) What is the 2D packing density of unit circles?
The answer in both cases is 6.
In 3-D the problem is more difficult. The answer has been known to be
'between 12 and 13' for a long time, but no one has been able to prove that
13 is not possible (until, apparently, now). The practical application is
that it defines the maximum packing density for things shaped like spheres,
e.g. ping-pong balls.
|
| 1475.2 | Tangentially speaking | VMSDEV::HALLYB | The Smart Money was on Goliath | Thu Aug 01 1991 19:02 | 6 |
| I wonder if this problem has applications in the chemistry (physics?)
field of "buckyballs" -- near spherical molecules of carbon, 60 or more
atoms to the molecule, arranged in geodesic spheres. Cheap and easy
to make.
John
|
| 1475.3 | soccerball example? | CIVAGE::LYNN | Lynn Yarbrough @WNP DTN 427-5663 | Wed Aug 14 1991 13:16 | 6 |
| Perhaps. Right now I can't find it, but I recall seeing a theorem to the
effect that (and I'm *really* stretching my memory) a geodesic sphere made
up of pentagons and hexagons must have exactly 12 pentagons. The degenerate
case of this is the dodecahedron, and I'm not sure if there is an
upper limit on the number of hexagons. Someone have a soccerball handy? I
think it has one hexagon between each pair of pentagons.
|