Convex polytopes A polytope may be
convex. The convex polytopes are the simplest kind of polytopes, and form the basis for several different generalizations of the concept of polytopes. A convex polytope is sometimes defined as the intersection of a set of
half-spaces. This definition allows a polytope to be neither bounded nor finite. Polytopes are defined in this way, e.g., in
linear programming. A polytope is
bounded if there is a ball of finite radius that contains it. A polytope is said to be
pointed if it contains at least one vertex. Every bounded nonempty polytope is pointed. An example of a non-pointed polytope is the set \{(x,y) \in \mathbb{R}^2 \mid x \geq 0\}. A polytope is
finite if it is defined in terms of a finite number of objects, e.g., as an intersection of a finite number of half-planes. It is an
integral polytope if all of its vertices have integer coordinates. A certain class of convex polytopes are
reflexive polytopes. An integral \mathcal{P} is reflexive if for some
integral matrix \mathbf{A}, \mathcal{P} = \{\mathbf{x} \in \mathbb{R}^d : \mathbf{Ax} \leq \mathbf{1}\}, where \mathbf{1} denotes a vector of all ones, and the inequality is component-wise. It follows from this definition that \mathcal{P} is reflexive if and only if (t+1)\mathcal{P}^\circ \cap \mathbb{Z}^d = t\mathcal{P} \cap \mathbb{Z}^d for all t \in \mathbb{Z}_{\geq 0}. In other words, a of \mathcal{P} differs, in terms of integer lattice points, from a of \mathcal{P} only by lattice points gained on the boundary. Equivalently, \mathcal{P} is reflexive if and only if its
dual polytope \mathcal{P}^* is an integral polytope.
Regular polytopes Regular polytopes have the highest degree of symmetry of all polytopes. The symmetry group of a regular polytope acts transitively on its
flags; hence, the
dual polytope of a regular polytope is also regular. There are three main classes of regular polytope which occur in any number of dimensions: •
Simplices, including the
equilateral triangle and the
regular tetrahedron. •
Hypercubes or measure polytopes, including the
square and the
cube. •
Orthoplexes or cross polytopes, including the
square and
regular octahedron. Dimensions two, three and four include regular figures which have fivefold symmetries and some of which are non-convex stars, and in two dimensions there are infinitely many
regular polygons of
n-fold symmetry, both convex and (for
n ≥ 5) star. But in higher dimensions there are no other regular polytopes. In three dimensions the convex
Platonic solids include the fivefold-symmetric
dodecahedron and
icosahedron, and there are also four star
Kepler-Poinsot polyhedra with fivefold symmetry, bringing the total to nine regular polyhedra. In four dimensions the
regular 4-polytopes include one additional convex solid with fourfold symmetry and two with fivefold symmetry. There are ten star
Schläfli-Hess 4-polytopes, all with fivefold symmetry, giving in all sixteen regular 4-polytopes.
Star polytopes A non-convex polytope may be self-intersecting; this class of polytopes include the
star polytopes. Some regular polytopes are stars. == Properties ==