Volume The
volume of an -simplex in -dimensional space with vertices is : \mathrm{Volume} = \frac{1}{n!} \left|\det \begin{pmatrix} v_1-v_0 && v_2-v_0 && \cdots && v_n-v_0 \end{pmatrix}\right| where each column of the
determinant is a
vector that points from vertex to another vertex . This formula is particularly useful when v_0 is the origin. The expression : \mathrm{Volume} = \frac{1}{n!} \det\left[ \begin{pmatrix} v_1^\text{T}-v_0^\text{T} \\ v_2^\text{T}-v_0^\text{T} \\ \vdots \\ v_n^\text{T}-v_0^\text{T} \end{pmatrix} \begin{pmatrix} v_1-v_0 & v_2-v_0 & \cdots & v_n-v_0 \end{pmatrix} \right]^{1/2} employs a
Gram determinant and works even when the -simplex's vertices are in a Euclidean space with more than dimensions, e.g., a triangle in \mathbf{R}^3. A more symmetric way to compute the volume of an -simplex in \mathbf{R}^n is : \mathrm{Volume} = {1\over n!} \left|\det \begin{pmatrix} v_0 & v_1 & \cdots & v_n \\ 1 & 1 & \cdots & 1 \end{pmatrix}\right|, and this can be extended to vertices in \mathbf{R}^m for , as times the square root of the difference of two
Gram determinants. Another common way of computing the volume of the simplex is via the
Cayley–Menger determinant, which works even when the n-simplex's vertices are in a Euclidean space with more than n dimensions. Without the it is the formula for the volume of an -
parallelotope. This can be understood as follows: Assume that is an -parallelotope constructed on a basis (v_0, e_1, \ldots, e_n) of \mathbf{R}^n. Given a
permutation \sigma of \{1,2,\ldots, n\}, call a list of vertices v_0,\ v_1, \ldots, v_n a -path if : v_1 = v_0 + e_{\sigma(1)},\ v_2 = v_1 + e_{\sigma(2)},\ldots, v_n = v_{n-1}+e_{\sigma(n)} (so there are -paths and v_n does not depend on the permutation). The following assertions hold: If is the unit -hypercube, then the union of the -simplexes formed by the convex hull of each -path is , and these simplexes are congruent and pairwise non-overlapping. In particular, the volume of such a simplex is : \frac{\operatorname{Vol}(P)}{n!} = \frac 1 {n!}. If is a general parallelotope, the same assertions hold except that it is no longer true, in dimension > 2, that the simplexes need to be pairwise congruent; yet their volumes remain equal, because the -parallelotope is the image of the unit -hypercube by the
linear isomorphism that sends the canonical basis of \mathbf{R}^n to e_1,\ldots, e_n. As previously, this implies that the volume of a simplex coming from a -path is: : \frac{\operatorname{Vol}(P)}{n!} = \frac{\det(e_1, \ldots, e_n)}{n!}. Conversely, given an -simplex (v_0,\ v_1,\ v_2,\ldots v_n) of \mathbf R^n, it can be supposed that the vectors e_1 = v_1-v_0,\ e_2 = v_2-v_1,\ldots e_n=v_n-v_{n-1} form a basis of \mathbf R^n. Considering the parallelotope constructed from v_0 and e_1,\ldots, e_n, one sees that the previous formula is valid for every simplex. Finally, the formula at the beginning of this section is obtained by observing that : \det(v_1-v_0, v_2-v_0,\ldots, v_n-v_0) = \det(v_1-v_0, v_2-v_1,\ldots, v_n-v_{n-1}). From this formula, it follows immediately that the volume under a standard -simplex (i.e. between the origin and the simplex in ) is : {1 \over (n+1)!} The volume of a regular -simplex with unit side length is : \frac{\sqrt{n+1}}{n!\sqrt{2^n}} as can be seen by multiplying the previous formula by , to get the volume under the -simplex as a function of its vertex distance from the origin, differentiating with respect to , at x=1/\sqrt{2} (where the -simplex side length is 1), and normalizing by the length dx/\sqrt{n+1} of the increment, (dx/(n+1),\ldots, dx/(n+1)), along the normal vector.
Dihedral angles of the regular n-simplex Any two -dimensional faces of a regular -dimensional simplex are themselves regular -dimensional simplices, and they have the same
dihedral angle of . This can be seen by noting that the center of the standard simplex is \left(\frac{1}{n+1}, \dots, \frac{1}{n+1}\right), and the centers of its faces are coordinate permutations of \left(0, \frac{1}{n}, \dots, \frac{1}{n}\right). Then, by symmetry, the vector pointing from \left(\frac{1}{n+1}, \dots, \frac{1}{n+1}\right) to \left(0, \frac{1}{n}, \dots, \frac{1}{n}\right) is perpendicular to the faces. So the vectors normal to the faces are permutations of (-n, 1, \dots, 1), from which the dihedral angles are calculated.
Simplices with an "orthogonal corner" An "orthogonal corner" means here that there is a vertex at which all adjacent edges are pairwise orthogonal. It immediately follows that all adjacent
faces are pairwise orthogonal. Such simplices are generalizations of right triangles and for them there exists an -dimensional version of the
Pythagorean theorem: The sum of the squared -dimensional volumes of the facets adjacent to the orthogonal corner equals the squared -dimensional volume of the facet opposite of the orthogonal corner. : \sum_{k=1}^n |A_k|^2 = |A_0|^2 where A_1 \ldots A_n are facets being pairwise orthogonal to each other but not orthogonal to A_0, which is the facet opposite the orthogonal corner. For a 2-simplex, the theorem is the
Pythagorean theorem for triangles with a right angle and for a 3-simplex it is
de Gua's theorem for a tetrahedron with an orthogonal corner.
Relation to the (n + 1)-hypercube The
Hasse diagram of the face lattice of an -simplex is isomorphic to the
graph of the -
hypercube's edges, with the hypercube's vertices mapping to each of the -simplex's elements, including the entire simplex and the null polytope as the extreme points of the lattice (mapped to two opposite vertices on the hypercube). This fact may be used to efficiently enumerate the simplex's face lattice, since more general face lattice enumeration algorithms are more computationally expensive. The -simplex is also the
vertex figure of the -hypercube. It is also the
facet of the -
orthoplex.
Topology Topologically, an -simplex is
equivalent to an
-ball. Every -simplex is an -dimensional
manifold with corners.
Probability In probability theory, the points of the standard -simplex in -space form the space of possible probability distributions on a finite set consisting of possible outcomes. The correspondence is as follows: For each distribution described as an ordered -tuple of probabilities whose sum is (necessarily) 1, we associate the point of the simplex whose
barycentric coordinates are precisely those probabilities. That is, the th vertex of the simplex is assigned to have the th probability of the -tuple as its barycentric coefficient. This correspondence is an affine homeomorphism.
Aitchison geometry Aitchinson geometry is a natural way to construct an
inner product space from the standard simplex \Delta^{D-1}. It defines the following operations on simplices and real numbers: ; Perturbation (addition) :: x \oplus y = \left[\frac{x_1 y_1}{\sum_{i=1}^D x_i y_i},\frac{x_2 y_2}{\sum_{i=1}^D x_i y_i}, \dots, \frac{x_D y_D}{\sum_{i=1}^D x_i y_i}\right] \qquad \forall x, y \in \Delta^{D-1} ; Powering (scalar multiplication) :: \alpha \odot x = \left[\frac{x_1^\alpha}{\sum_{i=1}^D x_i^\alpha},\frac{x_2^\alpha}{\sum_{i=1}^D x_i^\alpha}, \ldots,\frac{x_D^\alpha}{\sum_{i=1}^D x_i^\alpha} \right] \qquad \forall x \in \Delta^{D-1}, \; \alpha \in \mathbb{R} ; Inner product :: \langle x, y \rangle = \frac{1}{2D} \sum_{i=1}^D \sum_{j=1}^D \log \frac{x_i}{x_j} \log \frac{y_i}{y_j} \qquad \forall x, y \in \Delta^{D-1}
Compounds Since all simplices are self-dual, they can form a series of compounds; • Two triangles form a
hexagram {6/2}. • Two tetrahedra form a
compound of two tetrahedra or
stella octangula. • Two 5-cells form a
compound of two 5-cells in four dimensions. == Algebraic topology ==