July 25, 2008

  • Arrangements for...

    56 Triangles

    Greg Egan's drawing of the 56 triangles on the Klein quartic 3-hole torus

    "This wonderful picture was drawn by Greg Egan with the help of ideas from Mike Stay and Gerard Westendorp. It's probably the best way for a nonmathematician to appreciate the symmetry of Klein's quartic. It's a 3-holed torus, but drawn in a way that emphasizes the tetrahedral symmetry lurking in this surface! You can see there are 56 triangles: 2 for each of the tetrahedron's 4 corners, and 8 for each of its 6 edges."

    Exercise:

    The Eightfold Cube: The Beauty of Klein's Simple Group

    Click on image for further details.

    Note that if eight points are arranged
    in a cube (like the centers of the
    eight subcubes in the figure above),
    there are 56 triangles formed by
    the 8 points taken 3 at a time.

    Baez's discussion says that the Klein quartic's 56 triangles can be partitioned into 7 eight-triangle Egan "cubes" that correspond to the 7 points of the Fano plane in such a way that automorphisms of the Klein quartic correspond to automorphisms of the Fano plane. Show that the 56 triangles within the eightfold cube can also be partitioned into 7 eight-triangle sets that correspond to the 7 points of the Fano plane in such a way that (affine) transformations of the eightfold cube induce (projective) automorphisms of the Fano plane.

Post a Comment

Leave a Reply

Your email address will not be published. Required fields are marked *