Hypersimplex

Standard hypersimplices in ${\displaystyle {ℝ}^3}$

File:2D-simplex.svg
${\displaystyle {\mathrm{\Delta }}_{3,1}}$ Hyperplane: ${\displaystyle x+y+z=1}$	${\displaystyle {\mathrm{\Delta }}_{3,2}}$ Hyperplane: ${\displaystyle x+y+z=2}$

In polyhedral combinatorics, the hypersimplex ${\displaystyle {\mathrm{\Delta }}_{d,k}}$ is a convex polytope that generalizes the simplex. It is determined by two integers ${\displaystyle d}$ and ${\displaystyle k}$, and is defined as the convex hull of the ${\displaystyle d}$-dimensional vectors whose coefficients consist of ${\displaystyle k}$ ones and ${\displaystyle d-k}$ zeros. Equivalently, ${\displaystyle {\mathrm{\Delta }}_{d,k}}$ can be obtained by slicing the ${\displaystyle d}$-dimensional unit hypercube ${\displaystyle [0,1{]}^d}$ with the hyperplane of equation ${\displaystyle x_1+\cdots +x_d=k}$ and, for this reason, it is a ${\displaystyle (d-1)}$-dimensional polytope when ${\displaystyle 0<k<d}$.^[1]

The number of vertices of ${\displaystyle {\mathrm{\Delta }}_{d,k}}$ is ${\displaystyle (\genfrac{}{}{0ex}{}{d}{k})}$.^[1] The graph formed by the vertices and edges of the hypersimplex ${\displaystyle {\mathrm{\Delta }}_{d,k}}$ is the Johnson graph ${\displaystyle J(d,k)}$.^[2]

An alternative construction (for ${\displaystyle 0<k<d}$) is to take the convex hull of all ${\displaystyle (d-1)}$-dimensional ${\displaystyle (0,1)}$-vectors that have either ${\displaystyle k-1}$ or ${\displaystyle k}$ nonzero coordinates. This has the advantage of operating in a space that is the same dimension as the resulting polytope, but the disadvantage that the polytope it produces is less symmetric (although combinatorially equivalent to the result of the other construction).

The hypersimplex ${\displaystyle {\mathrm{\Delta }}_{d,k}}$ is also the matroid polytope for a uniform matroid with ${\displaystyle d}$ elements and rank ${\displaystyle k}$.^[3]

The hypersimplex ${\displaystyle {\mathrm{\Delta }}_{d,1}}$ is a ${\displaystyle (d-1)}$-simplex (and therefore, it has ${\displaystyle d}$ vertices). The hypersimplex ${\displaystyle {\mathrm{\Delta }}_{4,2}}$ is an octahedron, and the hypersimplex ${\displaystyle {\mathrm{\Delta }}_{5,2}}$ is a rectified 5-cell.

Generally, the hypersimplex, ${\displaystyle {\mathrm{\Delta }}_{d,k}}$, corresponds to a uniform polytope, being the ${\displaystyle (k-1)}$-rectified ${\displaystyle (d-1)}$-dimensional simplex, with vertices positioned at the center of all the ${\displaystyle (k-1)}$-dimensional faces of a ${\displaystyle (d-1)}$-dimensional simplex.

Examples Template:Math

Name	Equilateral triangle	Tetrahedron (3-simplex)	Octahedron	5-cell (4-simplex)	Rectified 5-cell	5-simplex	Rectified 5-simplex	Birectified 5-simplex
Template:Math	(3,1) (3,2)	(4,1) (4,3)	(4,2)	(5,1) (5,4)	(5,2) (5,3)	(6,1) (6,5)	(6,2) (6,4)	(6,3)
Vertices ${\displaystyle (\genfrac{}{}{0ex}{}{d}{k})}$	3	4	6	5	10	6	15	20
d-coordinates	(0,0,1) (0,1,1)	(0,0,0,1) (0,1,1,1)	(0,0,1,1)	(0,0,0,0,1) (0,1,1,1,1)	(0,0,0,1,1) (0,0,1,1,1)	(0,0,0,0,0,1) (0,1,1,1,1,1)	(0,0,0,0,1,1) (0,0,1,1,1,1)	(0,0,0,1,1,1)
Image	Error creating thumbnail:	File:Uniform polyhedron-33-t0.png	File:Uniform polyhedron-33-t1.svg	File:Schlegel wireframe 5-cell.png
Graphs	File:2-simplex t0.svg J(3,1) = K2	File:3-simplex t0.svg J(4,1) = K3	File:3-cube t2.svg J(4,2) = T(6,3)	File:4-simplex t0.svg J(5,1) = K4	J(5,2)	File:5-simplex t0.svg J(6,1) = K5	File:5-simplex t1 A4.svg J(6,2)	File:5-simplex t2 A4.svg J(6,3)
Coxeter diagrams	Template:CDD Template:CDD	Template:CDD Template:CDD	Template:CDD	Template:CDD Template:CDD	Template:CDD Template:CDD	Template:CDD Template:CDD	Template:CDD Template:CDD	Template:CDD
Schläfli symbols	{3} = r{3}	{3,3} = 2r{3,3}	r{3,3} = {3,4}	{3,3,3} = 3r{3,3,3}	r{3,3,3} = 2r{3,3,3}	{3,3,3,3} = 4r{3,3,3,3}	r{3,3,3,3} = 3r{3,3,3,3}	2r{3,3,3,3}
Facets	{ }	{3}		{3,3}	{3,3}, {3,4}	{3,3,3}	{3,3,3}, r{3,3,3}	r{3,3,3}

The hypersimplices were first studied and named in the computation of characteristic classes (an important topic in algebraic topology), by Template:Harvtxt.^[4][5]

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