Book contents
- Frontmatter
- Contents
- Preface
- 1 Classical Regular Polytopes
- 2 Regular Polytopes
- 3 Coxeter Groups
- 4 Amalgamation
- 5 Realizations
- 6 Regular Polytopes on Space-Forms
- 7 Mixing
- 8 Twisting
- 9 Unitary Groups and Hermitian Forms
- 10 Locally Toroidal 4-Polytopes: I
- 11 Locally Toroidal 4-Polytopes: II
- 12 Higher Toroidal Polytopes
- 13 Regular Polytopes Related to Linear Groups
- 14 Miscellaneous Classes of Regular Polytopes
- Bibliography
- Indices
- List of Symbols
- Author Index
- Subject Index
4 - Amalgamation
Published online by Cambridge University Press: 20 August 2009
- Frontmatter
- Contents
- Preface
- 1 Classical Regular Polytopes
- 2 Regular Polytopes
- 3 Coxeter Groups
- 4 Amalgamation
- 5 Realizations
- 6 Regular Polytopes on Space-Forms
- 7 Mixing
- 8 Twisting
- 9 Unitary Groups and Hermitian Forms
- 10 Locally Toroidal 4-Polytopes: I
- 11 Locally Toroidal 4-Polytopes: II
- 12 Higher Toroidal Polytopes
- 13 Regular Polytopes Related to Linear Groups
- 14 Miscellaneous Classes of Regular Polytopes
- Bibliography
- Indices
- List of Symbols
- Author Index
- Subject Index
Summary
A main thrust in the theory of regular polytopes is that of the amalgamation of polytopes of lower rank. Traditionally, the regular convex polytopes are constructed inductively, beginning with the regular polygons in the plane. The geometry of the ambient space considerably restricts the number of ways in which two regular convex n-polytopes P1 and P2 can occur as facets and vertex-figures, respectively, of a regular convex (n + 1)-polytope Q. Even when the simple necessary condition is satisfied that the vertex-figures of P1 are isomorphic to the facets of P2, the polytope Q need not exist in general. However, if we allow Q to be an infinite regular tessellation and the ambient space to be hyperbolic, then any two regular convex n-polytopes P1 and P2 can be “amalgamated” to form either a finite regular convex (n + 1)-polytope or an infinite regular tessellation of euclidean or hyperbolic n-space.
This amalgamation problem generalizes readily to abstract regular polytopes. Now, in the absence of an ambient geometry, obstructions to amalgamation must necessarily come from the combinatorics of the polytopes P1 and P2. Also, as a new phenomenon, if there does exist an abstract regular (n + 1)-polytope Q with facets P1 and vertex-figures P2, then in fact there can be many such polytopes, and all these are covered by a single polytope denoted {P1, P2}, and called the universal polytope.
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- Information
- Abstract Regular Polytopes , pp. 95 - 120Publisher: Cambridge University PressPrint publication year: 2002