eBook ISBN: | 978-1-4704-0351-5 |
Product Code: | MEMO/159/758.E |
List Price: | $62.00 |
MAA Member Price: | $55.80 |
AMS Member Price: | $37.20 |
eBook ISBN: | 978-1-4704-0351-5 |
Product Code: | MEMO/159/758.E |
List Price: | $62.00 |
MAA Member Price: | $55.80 |
AMS Member Price: | $37.20 |
-
Book DetailsMemoirs of the American Mathematical SocietyVolume: 159; 2002; 120 ppMSC: Primary 52; Secondary 19; 37; 46; 55; 82
This memoir develops, discusses and compares a range of commutative and non-commutative invariants defined for projection method tilings and point patterns. The projection method refers to patterns, particularly the quasiperiodic patterns, constructed by the projection of a strip of a high dimensional integer lattice to a smaller dimensional Euclidean space. In the first half of the memoir the acceptance domain is very general — any compact set which is the closure of its interior — while in the second half we concentrate on the so-called canonical patterns. The topological invariants used are various forms of \(K\)-theory and cohomology applied to a variety of both \(C^*\)-algebras and dynamical systems derived from such a pattern.
The invariants considered all aim to capture geometric properties of the original patterns, such as quasiperiodicity or self-similarity, but one of the main motivations is also to provide an accessible approach to the the \(K_0\) group of the algebra of observables associated to a quasicrystal with atoms arranged on such a pattern.
The main results provide complete descriptions of the (unordered) \(K\)-theory and cohomology of codimension 1 projection patterns, formulæ for these invariants for codimension 2 and 3 canonical projection patterns, general methods for higher codimension patterns and a closed formula for the Euler characteristic of arbitrary canonical projection patterns. Computations are made for the Ammann-Kramer tiling. Also included are qualitative descriptions of these invariants for generic canonical projection patterns. Further results include an obstruction to a tiling arising as a substitution and an obstruction to a substitution pattern arising as a projection. One corollary is that, generically, projection patterns cannot be derived via substitution systems.
ReadershipGraduate students and research mathematicians interested in convex and discrete geometry.
-
Table of Contents
-
Chapters
-
General introduction
-
I. Topological spaces and dynamical systems
-
II. Groupoids, $C$*-algebras, and their invariants
-
III. Approaches to calculation I: Cohomology for codimension one
-
IV. Approaches to calculation II: Infinitely generated cohomology
-
V. Approaches to calculation III: Cohomology for small codimension
-
-
RequestsReview Copy – for publishers of book reviewsPermission – for use of book, eBook, or Journal contentAccessibility – to request an alternate format of an AMS title
- Book Details
- Table of Contents
- Requests
This memoir develops, discusses and compares a range of commutative and non-commutative invariants defined for projection method tilings and point patterns. The projection method refers to patterns, particularly the quasiperiodic patterns, constructed by the projection of a strip of a high dimensional integer lattice to a smaller dimensional Euclidean space. In the first half of the memoir the acceptance domain is very general — any compact set which is the closure of its interior — while in the second half we concentrate on the so-called canonical patterns. The topological invariants used are various forms of \(K\)-theory and cohomology applied to a variety of both \(C^*\)-algebras and dynamical systems derived from such a pattern.
The invariants considered all aim to capture geometric properties of the original patterns, such as quasiperiodicity or self-similarity, but one of the main motivations is also to provide an accessible approach to the the \(K_0\) group of the algebra of observables associated to a quasicrystal with atoms arranged on such a pattern.
The main results provide complete descriptions of the (unordered) \(K\)-theory and cohomology of codimension 1 projection patterns, formulæ for these invariants for codimension 2 and 3 canonical projection patterns, general methods for higher codimension patterns and a closed formula for the Euler characteristic of arbitrary canonical projection patterns. Computations are made for the Ammann-Kramer tiling. Also included are qualitative descriptions of these invariants for generic canonical projection patterns. Further results include an obstruction to a tiling arising as a substitution and an obstruction to a substitution pattern arising as a projection. One corollary is that, generically, projection patterns cannot be derived via substitution systems.
Graduate students and research mathematicians interested in convex and discrete geometry.
-
Chapters
-
General introduction
-
I. Topological spaces and dynamical systems
-
II. Groupoids, $C$*-algebras, and their invariants
-
III. Approaches to calculation I: Cohomology for codimension one
-
IV. Approaches to calculation II: Infinitely generated cohomology
-
V. Approaches to calculation III: Cohomology for small codimension