Bose–Mesner algebra

In mathematics, a Bose–Mesner algebra is a special set of matrices which arise from a combinatorial structure known as an association scheme, together with the usual set of rules for combining (forming the products of) those matrices, such that they form an associative algebra, or, more precisely, a unitary commutative algebra. Among these rules are:

• the result of a product is also within the set of matrices,
• there is an identity matrix in the set, and
• taking products is commutative.

Bose–Mesner algebras have applications in physics to spin models, and in statistics to the design of experiments. They are named for R. C. Bose and Dale Marsh Mesner.^[1]

Let X be a set of v elements. Consider a partition of the 2-element subsets of X into n non-empty subsets, R₁, ..., R_n such that:

• given an ${\displaystyle x\in X}$, the number of ${\displaystyle y\in X}$ such that ${\displaystyle \{x,y\}\in R_i}$ depends only on i (and not on x). This number will be denoted by v_i, and
• given ${\displaystyle x,y\in X}$ with ${\displaystyle \{x,y\}\in R_k}$, the number of ${\displaystyle z\in X}$ such that ${\displaystyle \{x,z\}\in R_i}$ and ${\displaystyle \{z,y\}\in R_j}$ depends only on i,j and k (and not on x and y). This number will be denoted by ${\displaystyle p_{ij}^k}$.

This structure is enhanced by adding all pairs of repeated elements of X and collecting them in a subset R₀. This enhancement permits the parameters i, j, and k to take on the value of zero, and lets some of x,y or z be equal.

A set with such an enhanced partition is called an association scheme.^[2] One may view an association scheme as a partition of the edges of a complete graph (with vertex set X) into n classes, often thought of as color classes. In this representation, there is a loop at each vertex and all the loops receive the same 0th color.

The association scheme can also be represented algebraically. Consider the matrices D_i defined by:

${\displaystyle (D_i{)}_{x,y}=\{\begin{array}{ll}1,& \text{if }(x,y)\in R_i,\\ 0,& \text{otherwise.}\end{array}(1)}$

Let ${\displaystyle {𝒜}}$ be the vector space consisting of all matrices ${\displaystyle \sum _{i=0}^n{a}_i{D}_i}$, with ${\displaystyle a_i}$ complex.^[3][4]

The definition of an association scheme is equivalent to saying that the ${\displaystyle D_i}$ are v × v (0,1)-matrices which satisfy

1. ${\displaystyle D_i}$ is symmetric,
2. ${\displaystyle {\displaystyle \sum _{i=0}^n}{D}_i=J}$ (the all-ones matrix),
3. ${\displaystyle D_0=I,}$
4. ${\displaystyle D_i{D}_j={\displaystyle \sum _{k=0}^n}{p}_{ij}^k{D}_k=D_j{D}_i,i,j=0,\dots ,n.}$

The (x,y)-th entry of the left side of 4. is the number of two colored paths of length two joining x and y (using "colors" i and j) in the graph. Note that the rows and columns of ${\displaystyle D_i}$ contain ${\displaystyle v_i}$ 1s:

${\displaystyle D_{i}J=J{D}_i=v_{i}J.(2)}$

From 1., these matrices are symmetric. From 2., ${\displaystyle D_0,\dots ,D_n}$ are linearly independent, and the dimension of ${\displaystyle {𝒜}}$ is ${\displaystyle n+1}$. From 4., ${\displaystyle {𝒜}}$ is closed under multiplication, and multiplication is always associative. This associative commutative algebra ${\displaystyle {𝒜}}$ is called the Bose–Mesner algebra of the association scheme. Since the matrices in ${\displaystyle {𝒜}}$ are symmetric and commute with each other, they can be simultaneously diagonalized. This means that there is a matrix ${\displaystyle S}$ such that to each ${\displaystyle A\in {𝒜}}$ there is a diagonal matrix ${\displaystyle {\mathrm{\Lambda }}_A}$ with ${\displaystyle S^{-1}AS={\mathrm{\Lambda }}_A}$. This means that ${\displaystyle {𝒜}}$ is semi-simple and has a unique basis of primitive idempotents ${\displaystyle J_0,\dots ,J_n}$. These are complex n × n matrices satisfying

${\displaystyle J_i^2=J_i,i=0,\dots ,n,(3)}$

${\displaystyle J_i{J}_k=0,i\ne k,(4)}$

${\displaystyle {\displaystyle \sum _{i=0}^n}{J}_i=I.(5)}$

The Bose–Mesner algebra has two distinguished bases: the basis consisting of the adjacency matrices ${\displaystyle D_i}$, and the basis consisting of the irreducible idempotent matrices ${\displaystyle E_k}$. By definition, there exist well-defined complex numbers such that

${\displaystyle D_i={\displaystyle \sum _{k=0}^n}{p}_i(k)E_k,(6)}$

and

${\displaystyle |X|E_k={\displaystyle \sum _{i=0}^n}{q}_k\left(i\right)D_i.(7)}$

The p-numbers ${\displaystyle p_i(k)}$, and the q-numbers ${\displaystyle q_k(i)}$, play a prominent role in the theory.^[5] They satisfy well-defined orthogonality relations. The p-numbers are the eigenvalues of the adjacency matrix ${\displaystyle D_i}$.

The eigenvalues of ${\displaystyle p_i(k)}$ and ${\displaystyle q_k(i)}$, satisfy the orthogonality conditions:

${\displaystyle {\displaystyle \sum _{k=0}^n}{\mu }_i{p}_i(k)p_{\ell }(k)=v{v}_i{\delta }_{i\ell },(8)}$

${\displaystyle {\displaystyle \sum _{k=0}^n}{\mu }_i{q}_k(i)q_{\ell }(i)=v{\mu }_k{\delta }_{k\ell }.(9)}$

Also

${\displaystyle {\mu }_j{p}_i(j)=v_i{q}_j(i),i,j=0,\dots ,n.(10)}$

In matrix notation, these are

${\displaystyle P^T{\mathrm{\Delta }}_{\mu }P=v{\mathrm{\Delta }}_v,(11)}$

${\displaystyle Q^T{\mathrm{\Delta }}_{v}Q=v{\mathrm{\Delta }}_{\mu },(12)}$

where ${\displaystyle {\mathrm{\Delta }}_v=\mathrm{diag}\{v_0,v_1,\dots ,v_n\},{\mathrm{\Delta }}_{\mu }=\mathrm{diag}\{{\mu }_0,{\mu }_1,\dots ,{\mu }_n\}.}$

The eigenvalues of ${\displaystyle D_i{D}_{\ell }}$ are ${\displaystyle p_i(k)p_{\ell }(k)}$ with multiplicities ${\displaystyle {\mu }_k}$. This implies that

${\displaystyle v{v}_i{\delta }_{i\ell }=\mathrm{trace}{D}_i{D}_{\ell }={\displaystyle \sum _{k=0}^n}{\mu }_i{p}_i(k)p_{\ell }(k),(13)}$

which proves Equation ${\displaystyle \left(8\right)}$ and Equation ${\displaystyle \left(11\right)}$,

${\displaystyle Q=v{P}^{-1}={\mathrm{\Delta }}_v^{-1}{P}^T{\mathrm{\Delta }}_{\mu },(14)}$

which gives Equations ${\displaystyle (9)}$, ${\displaystyle (10)}$ and ${\displaystyle (12)}$.${\displaystyle ◻}$

There is an analogy between extensions of association schemes and extensions of finite fields. The cases we are most interested in are those where the extended schemes are defined on the ${\displaystyle n}$-th Cartesian power ${\displaystyle X={{ℱ}}^n}$ of a set ${\displaystyle {ℱ}}$ on which a basic association scheme ${\displaystyle ({ℱ},K)}$ is defined. A first association scheme defined on ${\displaystyle X={{ℱ}}^n}$ is called the ${\displaystyle n}$-th Kronecker power ${\displaystyle {({ℱ},K)}_{\otimes }^n}$ of ${\displaystyle ({ℱ},K)}$. Next the extension is defined on the same set ${\displaystyle X={{ℱ}}^n}$ by gathering classes of ${\displaystyle {({ℱ},K)}_{\otimes }^n}$. The Kronecker power corresponds to the polynomial ring ${\displaystyle F\left[X\right]}$ first defined on a field ${\displaystyle \mathbb{𝔽}}$, while the extension scheme corresponds to the extension field obtained as a quotient. An example of such an extended scheme is the Hamming scheme.

Association schemes may be merged, but merging them leads to non-symmetric association schemes, whereas all usual codes are subgroups in symmetric Abelian schemes.^[6][7][8]

• Association scheme

• Bailey, Rosemary A. (2004), Association schemes: Designed experiments, algebra and combinatorics, Cambridge Studies in Advanced Mathematics, 84, Cambridge University Press, pp. 387, ISBN 978-0-521-82446-0, http://www.maths.qmul.ac.uk/~rab/Asbook 
• Bannai, Eiichi; Ito, Tatsuro (1984), Algebraic combinatorics I: Association schemes, Menlo Park, CA: The Benjamin/Cummings Publishing Co., Inc., pp. xxiv+425, ISBN 0-8053-0490-8 
• Bannai, Etsuko (2001), "Bose–Mesner algebras associated with four-weight spin models", Graphs and Combinatorics 17 (4): 589–598, doi:10.1007/PL00007251 
• Bose, R. C.; Mesner, D. M. (1959), "On linear associative algebras corresponding to association schemes of partially balanced designs", Annals of Mathematical Statistics 30 (1): 21–38, doi:10.1214/aoms/1177706356, http://projecteuclid.org/euclid.aoms/1177706356 
• Cameron, P. J.; van Lint, J. H. (1991), Designs, Graphs, Codes and their Links, Cambridge: Cambridge University Press, ISBN 0-521-42385-6, https://archive.org/details/designsgraphscod0000came 
• Camion, P. (1998), "Codes and association schemes: Basic properties of association schemes relevant to coding", in Pless, V. S.; Huffman, W. C., Handbook of coding theory, The Netherlands: Elsevier 
• Delsarte, P.; Levenshtein, V. I. (1998), "Association schemes and coding theory", IEEE Transactions on Information Theory 44 (6): 2477–2504, doi:10.1109/18.720545 
• MacWilliams, F. J.; Sloane, N. J. A. (1978), The theory of error-correcting codes, New York: Elsevier 
• Nomura, K. (1997), "An algebra associated with a spin model", Journal of Algebraic Combinatorics 6 (1): 53–58, doi:10.1023/A:1008644201287 

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