In mathematics, a Bratteli diagram is a combinatorial structure: a graph composed of vertices labelled by positive integers ("level") and unoriented edges between vertices having levels differing by one. The notion was introduced by Ola Bratteli in 1972 in the theory of operator algebras to describe directed sequences of finite-dimensional algebras: it played an important role in Elliott's classification of AF-algebras and the theory of subfactors. Subsequently Anatoly Vershik associated dynamical systems with infinite paths in such graphs.
A Bratteli diagram is given by the following objects:
A customary way to pictorially represent Bratteli diagrams is to align the vertices according to their levels, and put the number b<sub>v</sub> beside the vertex v, or use that number in place of v, as in
An ordered Bratteli diagram is a Bratteli diagram together with a partial order on E<sub>n</sub> such that for any v â V<sub>n</sub> the set { e â E<sub>nâÂÂ1</sub> : r(e) = v } is totally ordered. Edges that do not share a common range vertex are incomparable. This partial order allows us to define the set of all maximal edges E<sub>max</sub> and the set of all minimal edges E<sub>min</sub>. A Bratteli diagram with a unique infinitely long path in E<sub>max</sub> and E<sub>min</sub> is called essentially simple.
Any semisimple algebra over the complex numbers C of finite dimension can be expressed as a direct sum âÂÂ<sub>k</sub> M<sub>n<sub>k</sub></sub>(C) of matrix algebras, and the C-algebra homomorphisms between two such algebras up to inner automorphisms on both sides are completely determined by the multiplicity number between 'matrix algebra' components. Thus, an injective homomorphism of âÂÂ<sub>k=1</sub><sup>i</sup> M<sub>n<sub>k</sub></sub>(C) into âÂÂ<sub>l=1</sub><sup>j</sup> M<sub>m<sub>l</sub></sub>(C) may be represented by a collection of positive numbers a<sub>k, l</sub> satisfying ã n<sub>k</sub> a<sub>k, l</sub> ⤠m<sub>l</sub>. (The equality holds if and only if the homomorphism is unital; we can allow non-injective homomorphisms by allowing some a<sub>k,l</sub> to be zero.) This can be illustrated as a bipartite graph having the vertices marked by numbers (n<sub>k</sub>)<sub>k</sub> on one hand and the ones marked by (m<sub>l</sub>)<sub>l</sub> on the other hand, and having a<sub>k, l</sub> edges between the vertex n<sub>k</sub> and the vertex m<sub>l</sub>.
Thus, when we have a sequence of finite-dimensional semisimple algebras A<sub>n</sub> and injective homomorphisms ÃÂ<sub>n</sub> : A<sub>n</sub> â A<sub>n+1</sub>: between them, we obtain a Bratteli diagram by putting
(each isomorphic to a matrix algebra), marked by the size of matrices.
Any semisimple algebra (possibly of infinite dimension) is one whose modules are completely reducible, i.e. they decompose into the direct sum of simple modules. Let be a chain of split semisimple algebras, and let be the indexing set for the irreducible representations of . Denote by the irreducible module indexed by . Because of the inclusion , any -module restricts to a -module. Let denote the decomposition numbers
The Bratteli diagram for the chain is obtained by placing one vertex for every element of on level and connecting a vertex on level to a vertex on level with edges.
(1) If , the ith symmetric group, the corresponding Bratteli diagram is the same as Young's lattice.
(2) If is the Brauer algebra or the BirmanâÂÂWenzl algebra on i strands, then the resulting Bratteli diagram has partitions of iâÂÂ2k (for ) with one edge between partitions on adjacent levels if one can be obtained from the other by adding or subtracting 1 from a single part.
(3) If is the TemperleyâÂÂLieb algebra on i strands, the resulting Bratteli has integers iâÂÂ2k (for ) with one edge between integers on adjacent levels if one can be obtained from the other by adding or subtracting 1.