Truncated tesseract

Tesseract	Truncated tesseract	Rectified tesseract	Bitruncated tesseract
Schlegel diagrams centered on [4,3] (cells visible at [3,3])
16-cell	Truncated 16-cell	Rectified 16-cell (24-cell)	Bitruncated tesseract
Schlegel diagrams centered on [3,3] (cells visible at [4,3])

In geometry, a truncated tesseract is a uniform 4-polytope formed as the truncation of the regular tesseract.

There are three truncations, including a bitruncation, and a tritruncation, which creates the truncated 16-cell.

Truncated tesseract

Truncated tesseract
Schlegel diagram (tetrahedron cells visible)
Type	Uniform 4-polytope
Schläfli symbol	t{4,3,3}
Coxeter diagrams
Cells	24	8 3.8.8 16 3.3.3
Faces	88	64 {3} 24 {8}
Edges	128
Vertices	64
Vertex figure	80px Isosceles triangular pyramid
Dual	Tetrakis 16-cell
Symmetry group	B₄, [4,3,3], order 384
Properties	convex
Uniform index	12 13 14

The truncated tesseract is bounded by 24 cells: 8 truncated cubes, and 16 tetrahedra.

Alternate names

Truncated tesseract (Norman W. Johnson)
Truncated tesseract (Acronym tat) (George Olshevsky, and Jonathan Bowers)^[1]

Construction

The truncated tesseract may be constructed by truncating the vertices of the tesseract at $1/(\sqrt{2}+2)$ of the edge length. A regular tetrahedron is formed at each truncated vertex.

The Cartesian coordinates of the vertices of a truncated tesseract having edge length 2 is given by all permutations of:

\left(\pm1,\ \pm(1+\sqrt{2}),\ \pm(1+\sqrt{2}),\ \pm(1+\sqrt{2})\right)

Projections

File:3D stereoscopic projection truncated tesseract.PNG

A stereoscopic 3D projection of a truncated tesseract.

In the truncated cube first parallel projection of the truncated tesseract into 3-dimensional space, the image is laid out as follows:

The projection envelope is a cube.
Two of the truncated cube cells project onto a truncated cube inscribed in the cubical envelope.
The other 6 truncated cubes project onto the square faces of the envelope.
The 8 tetrahedral volumes between the envelope and the triangular faces of the central truncated cube are the images of the 16 tetrahedra, a pair of cells to each image.

Images

orthographic projections
Coxeter plane	B₄	B₃ / D₄ / A₂	B₂ / D₃
Graph		100px	100px
Dihedral symmetry	[8]	[6]	[4]
Coxeter plane	F₄	A₃
Graph	100px	100px
Dihedral symmetry	[12/3]	[4]

A polyhedral net	200px Truncated tesseract projected onto the 3-sphere with a stereographic projection into 3-space.

Related polytopes

The truncated tesseract, is third in a sequence of truncated hypercubes:

Truncated hypercubes
							...
Octagon	Truncated cube	Truncated tesseract	Truncated 5-cube	Truncated 6-cube	Truncated 7-cube	Truncated 8-cube

Bitruncated tesseract

Bitruncated tesseract
Two Schlegel diagrams, centered on truncated tetrahedral or truncated octahedral cells, with alternate cell types hidden.
Type	Uniform 4-polytope
Schläfli symbol	2t{4,3,3} 2t{3,3^1,1} h_2,3{4,3,3}
Coxeter diagrams	=
Cells	24	8 4.6.6 16 3.6.6
Faces	120	32 {3} 24 {4} 64 {6}
Edges	192
Vertices	96
Vertex figure	60px 60px Digonal disphenoid
Symmetry group	B₄, [3,3,4], order 384 D₄, [3^1,1,1], order 192
Properties	convex, vertex-transitive
Uniform index	15 16 17

File:Tesseractihexadecachoron net.png

Net

The bitruncated tesseract, bitruncated 16-cell, or tesseractihexadecachoron is constructed by a bitruncation operation applied to the tesseract. It can also be called a runcicantic tesseract with half the vertices of a runcicantellated tesseract with a construction.

Alternate names

Bitruncated tesseract/Runcicantic tesseract (Norman W. Johnson)
Bitruncated tesseract (Acronym tah) (George Olshevsky, and Jonathan Bowers)^[2]

Construction

A tesseract is bitruncated by truncating its cells beyond their midpoints, turning the eight cubes into eight truncated octahedra. These still share their square faces, but the hexagonal faces form truncated tetrahedra which share their triangular faces with each other.

The Cartesian coordinates of the vertices of a bitruncated tesseract having edge length 2 is given by all permutations of:

\left(0,\ \pm\sqrt{2},\ \pm2\sqrt{2},\ \pm2\sqrt{2}\right)

Structure

The truncated octahedra are connected to each other via their square faces, and to the truncated tetrahedra via their hexagonal faces. The truncated tetrahedra are connected to each other via their triangular faces.

Projections

orthographic projections
Coxeter plane	B₄	B₃ / D₄ / A₂	B₂ / D₃
Graph			100px
Dihedral symmetry	[8]	[6]	[4]
Coxeter plane	F₄	A₃
Graph	100px	100px
Dihedral symmetry	[12/3]	[4]

Stereographic projections

The truncated-octahedron-first projection of the bitruncated tesseract into 3D space has a truncated cubical envelope. Two of the truncated octahedral cells project onto a truncated octahedron inscribed in this envelope, with the square faces touching the centers of the octahedral faces. The 6 octahedral faces are the images of the remaining 6 truncated octahedral cells. The remaining gap between the inscribed truncated octahedron and the envelope are filled by 8 flattened truncated tetrahedra, each of which is the image of a pair of truncated tetrahedral cells.

Stereographic projections
		200px Colored transparently with pink triangles, blue squares, and gray hexagons

Related polytopes

The bitruncated tesseract is second in a sequence of bitruncated hypercubes:

Bitruncated hypercubes
						...
Bitruncated cube	Bitruncated tesseract	Bitruncated 5-cube	Bitruncated 6-cube	Bitruncated 7-cube	Bitruncated 8-cube

Truncated 16-cell

Truncated 16-cell Cantic tesseract
Schlegel diagram (octahedron cells visible)
Type	Uniform 4-polytope
Schläfli symbol	t{4,3,3} t{3,3^1,1} h₂{4,3,3}
Coxeter diagrams	=
Cells	24	8 3.3.3.3 16 3.6.6
Faces	96	64 {3} 32 {6}
Edges	120
Vertices	48
Vertex figure	50px 50px square pyramid
Dual	Hexakis tesseract
Coxeter groups	B₄ [3,3,4], order 384 D₄ [3^1,1,1], order 192
Properties	convex
Uniform index	16 17 18

The truncated 16-cell, truncated hexadecachoron, cantic tesseract which is bounded by 24 cells: 8 regular octahedra, and 16 truncated tetrahedra. It has half the vertices of a cantellated tesseract with construction .

It is related to, but not to be confused with, the 24-cell, which is a regular 4-polytope bounded by 24 regular octahedra.