g4g9
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G4G9. A 10 -dimensional Jewel. Carlo H. Séquin. EECS Computer Science Division University of California, Berkeley. What Is a Regular Polytope ?. “Polytope” is the generalization of the terms “Polygon” (2D), “Polyhedron” (3D), “Polychoron” (4D), … to arbitrary dimensions. - PowerPoint PPT PresentationTRANSCRIPT
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G4G9G4G9
A 10-dimensional Jewel
EECS Computer Science DivisionEECS Computer Science DivisionUniversity of California, BerkeleyUniversity of California, Berkeley
Carlo H. Séquin
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What Is a Regular Polytope ?What Is a Regular Polytope ? “Polytope”
is the generalization of the terms “Polygon” (2D), “Polyhedron” (3D), “Polychoron” (4D), …to arbitrary dimensions.
“Regular”means: All the vertices, edges, faces, cells…are indistinguishable from each another.
Examples in 2D: Regular n-gons:
There are infinitely many of them!
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In 3 Dimensions . . . In 3 Dimensions . . .
There are only 5 Platonic solids:
They are composed from the regular 2D polygons.
Only triangles, squares, and pentagons are useful: other n-gons are too ”round”;they cannot form nice 3D corners.
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In 4D Space . . .In 4D Space . . .
The same constructive approach continues:
We can use the Platonic solids as building blocks to form the “crust” of regular 4D polychora.
Only 6 constructions are successful.
Only 4 of the 5 Platonic solids can be used; the icosahedron is too round (dihedral angle > 120°).
This is the result . . .
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The 6 Regular Polychora in 4-D . . .The 6 Regular Polychora in 4-D . . .
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120-Cell 120-Cell ( 600V, 1200E, 720F )( 600V, 1200E, 720F )
Cell-first,extremeperspectiveprojection
Z-Corp. model
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600-Cell 600-Cell ( 120V, 720E, 1200F ) (parallel proj.)( 120V, 720E, 1200F ) (parallel proj.)
David Richter
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In Higher-Dimensional Spaces . . . In Higher-Dimensional Spaces . . .
We can recursively construct new regular polytopes
Using the ones from one dimension lower spceas the boundary (“surface”) element.
But from dimension 5 onwards, there are just 3 each:
N-Simplices (like tetrahedron)
N-Cubes (hypercubes, measure-polytopes)
N-Orthoplexes (cross-polytopes = duals of n-cube)
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Thinking Outside the Box . . .Thinking Outside the Box . . .
Allow polyhedron faces to intersect . . .
or even to be self-intersecting:
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In 3D: In 3D: Kepler-Poinsot Solids Kepler-Poinsot Solids
Mutually intersecting faces: (all)
Faces in the form of pentagrams: (3,4)
+ 10 such objects in 4D space !
Gr. Dodeca, Gr. Icosa, Gr. Stell. Dodeca, Sm. Stell. Dodeca
1 2 3 4
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Single-Sided Polychora in 4DSingle-Sided Polychora in 4D
Let’s allow single-sided polytope constructions like a Möbius band or a Klein bottle.
In 4D we can make objects that close on themselves;they have the topology of the projective plane.
The simplest one is the hemi-cube . . .
But we can do even wilder things ...
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Hemi-CubeHemi-Cube Single-sided; not a solid any more!
Has the connectivity of the projective plane!
3 faces only vertex graph K4 3 saddle faces
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Physical Model of a Hemi-cubePhysical Model of a Hemi-cube
Made on a Fused-Deposition Modeling Machine
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Hemi-DodecahedronHemi-Dodecahedron
A self-intersecting, single-sided 3D cell Is only geometrically regular in 9D space
connect oppositeperimeter points
connectivity: Petersen graph
six warped pentagons
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Hemi-IcosahedronHemi-Icosahedron
A self-intersecting, single-sided 3D cell Is only geometrically regular in 5D
This is the BUILDING BLOCK for the 10D JEWEL !
connect oppositeperimeter points
connectivity: graph K6
5-D simplex;warped octahedron
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The Complete Connectivity DiagramThe Complete Connectivity Diagram
From: Coxeter [2], colored by Tom Ruen
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Combining Two CellsCombining Two Cells
A highly confusing, intersecting mess!
Add new cells on the inside !
All the edges of the first 5 cells.
Starter cell with4 tetra faces
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Six More Cells !Six More Cells !
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Regular Hendecachoron (11-Cell)Regular Hendecachoron (11-Cell)
11 vertices, 55 edges, 55 faces, 11 cells self dual
Solid faces Transparency
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The Full 11-CellThe Full 11-Cell
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The The 1010D Jewel D Jewel
– a building block of our universe ?
660 automorphisms
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Hands-on Construction ProjectHands-on Construction Project
This afternoon we will build card-board models of the hemi-icosahedron.
Thanks to Chris Palmer (now at U.C. Berkeley):
for designing the parameterized template and for laser cutting the 30 colored parts.
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What Is the 11-Cell Good For ?What Is the 11-Cell Good For ?
A neat mathematical object !
A piece of “absolute truth”:(Does not change with style, new experiments)
A 10-dimensional building block …(Physicists believe Universe may be 10-D)
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Are there More Polychora Like This ?Are there More Polychora Like This ?
Yes – one more: the 57-Cell
Built from 57 Hemi-dodecahedra
5 such single-sided cells join around edges
It is also self-dual: 57 V, 171 E, 171 F, 57 C.
I may talk about it at G4G57 . . .