[math-fun] mechanical realization of a 3-torus
I have an idea for a physical mathematical demo, and I'm wondering if anyone has any thoughts about it (or any interest in actually building it). Spitzer's "random flight theorem" says that a sum of n independent random unit vectors in the plane has a probability of exactly 1/(n+1) of having magnitude less than 1. In particular, the chance that the sum of 3 independent random unit vectors has magnitude less than 1 is exactly 1/4. It so happens that this particular fact can be deduced from the following geometrical fact, which may or may not be new: If u, v, and w are unit vectors, then exactly two of the eight vectors +u+v+w, +u+v-w, +u-v+w, +u-v-w, -u+v+w, -u+v-w, -u-v+w, -u-v-w have magnitude less than 1 (except in the case when some of these vectors have magnitude exactly 1). There's a nice way to physically model this "two out of eight" fact with a linkage consisting of bars of length 2, so that eight points move jointly so as to trace out the configuration space {(+u+v+w, +u+v-w, +u-v+w, +u-v-w, -u+v+w, -u+v-w, -u-v+w, -u-v-w): |u|=|v|=|w|=1}. Now imagine that the bars are made of a transparent material like plexiglass, and that the model has a backing that shows a disk of radius 1 centered at 0. As you move around in configuration space, there are always exactly two points that lie inside the disk, except for the borderline case where four (or more) points lie on the boundary of the disk. I'm wondering if this might make a good object for the Museum of Mathematics, or maybe just a fun object to own and to display in my office. I think I know what happens to the configuration space if you pin down one of the eight points, but it'd be cool to really feel what happens. Note that one could describe this linkage simply as a mechanical realization of a 3-torus (hence the title of this post). Jim
I haven't understood how this linkage is intended to function --- but have you considered a simulation in Mathematica or Maple; or more satisfactorily, Java / Javaview or GeomView? WFL On 9/10/10, James Propp <jpropp@cs.uml.edu> wrote:
I have an idea for a physical mathematical demo, and I'm wondering if anyone has any thoughts about it (or any interest in actually building it).
Spitzer's "random flight theorem" says that a sum of n independent random unit vectors in the plane has a probability of exactly 1/(n+1) of having magnitude less than 1. In particular, the chance that the sum of 3 independent random unit vectors has magnitude less than 1 is exactly 1/4. It so happens that this particular fact can be deduced from the following geometrical fact, which may or may not be new: If u, v, and w are unit vectors, then exactly two of the eight vectors +u+v+w, +u+v-w, +u-v+w, +u-v-w, -u+v+w, -u+v-w, -u-v+w, -u-v-w have magnitude less than 1 (except in the case when some of these vectors have magnitude exactly 1).
There's a nice way to physically model this "two out of eight" fact with a linkage consisting of bars of length 2, so that eight points move jointly so as to trace out the configuration space {(+u+v+w, +u+v-w, +u-v+w, +u-v-w, -u+v+w, -u+v-w, -u-v+w, -u-v-w): |u|=|v|=|w|=1}. Now imagine that the bars are made of a transparent material like plexiglass, and that the model has a backing that shows a disk of radius 1 centered at 0. As you move around in configuration space, there are always exactly two points that lie inside the disk, except for the borderline case where four (or more) points lie on the boundary of the disk.
I'm wondering if this might make a good object for the Museum of Mathematics, or maybe just a fun object to own and to display in my office. I think I know what happens to the configuration space if you pin down one of the eight points, but it'd be cool to really feel what happens.
Note that one could describe this linkage simply as a mechanical realization of a 3-torus (hence the title of this post).
Jim
_______________________________________________ math-fun mailing list math-fun@mailman.xmission.com http://mailman.xmission.com/cgi-bin/mailman/listinfo/math-fun
participants (2)
-
Fred lunnon -
James Propp