Schlegel diagram

From Wikipedia, the free encyclopedia

Examples colored by the number of sides on each face. Yellow triangles, red squares, and green pentagons.
Examples colored by the number of sides on each face. Yellow triangles, red squares, and green pentagons.
A hypercube projected into 3-space as a Schlegel diagram. There are 8 cubic cells visible, one in the center, one below each of the six exterior faces, and the last one is inside-out representing the space outside the cubic boundary.
A hypercube projected into 3-space as a Schlegel diagram. There are 8 cubic cells visible, one in the center, one below each of the six exterior faces, and the last one is inside-out representing the space outside the cubic boundary.
A 120-cell with edges projected onto a hypersphere, stereographic projection to 3-space
A 120-cell with edges projected onto a hypersphere, stereographic projection to 3-space

In geometry, a Schlegel diagram is a special projection of a polytope down one dimension. It projects polyhedra to a plane figure, and polychora to 3-space. It is used as a visual aid in seeing the topological connectivity of the polytope edges.

It can be constructed by a perspective projection viewed from a point outside of the polytope, above the center of a facet. All vertices and edges of the polytope are projected onto a hyperplane of that facet. If the polytope is convex a point near the facet will exist which maps the facet outside, and all other facets inside, so no edges need to cross in the projection.

The simplest way to guarantee this projection results in nonoverlapping edges on a general convex polytope is to first project all the vertices onto an n-sphere, and then perform a stereographic projection. The edges can appear curved in the final diagram if they are also mapped onto the n-sphere.

The easiest way of drawing a Schlegel Diagram is to 'project' the skeleton of the shape into one side.

[edit] See also

  • Net (polyhedron) - A different approach for visualization by lowering the dimension of a polytope is to build a net, disconnecting facets, and unfolding until the facets can exist on a single hyperplane. This maintains the geometric scale and shape, but makes the topological connections harder to see.

[edit] References

[edit] External links


Languages