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Conference matrix

In mathematics, a conference matrix (also called a C-matrix) is a square matrix C with 0 on the diagonal and +1 and −1 off the diagonal, such that CTC is a multiple of the identity matrix I. Thus, if the matrix has order n, CTC = (n−1)I. Some authors use a more general definition, which requires there to be a single 0 in each row and column but not necessarily on the diagonal.

Symmetric conference matrices
If C is a symmetric conference matrix of order n > 1, then not only must n be congruent to 2 mod 4 but also n − 1 must be a sum of two squares; there is a clever proof by elementary matrix theory in van Lint and Seidel. Given a symmetric conference matrix, the matrix S can be viewed as the Seidel adjacency matrix of a graph. The graph has n − 1 vertices, corresponding to the rows and columns of S, and two vertices are adjacent if the corresponding entry in S is negative. This graph is strongly regular of the type called (after the matrix) a conference graph. The existence of conference matrices of orders n allowed by the above restrictions is known only for some values of n. For instance, if n = q + 1 where q is a prime power congruent to 1 mod 4, then the Paley graphs provide examples of symmetric conference matrices of order n, by taking S to be the Seidel matrix of the Paley graph. The first few possible orders of a symmetric conference matrix are n = 2, 6, 10, 14, 18, (not 22, since 21 is not a sum of two squares), 26, 30, (not 34 since 33 is not a sum of two squares), 38, 42, 46, 50, 54, (not 58), 62 ; for every one of these, it is known that a symmetric conference matrix of that order exists. Order 66 seems to be an open problem. Examples The essentially unique conference matrix of order 6 is given by :\begin{pmatrix}0 &+1 &+1 &+1 &+1& +1\\+1& 0 &+1 &-1 &-1& +1\\+1& +1& 0 &+1 &-1& -1\\+1& -1& +1& 0 &+1& -1\\+1& -1& -1& +1& 0& +1\\+1& +1& -1& -1& +1& 0 \end{pmatrix}. All other conference matrices of order 6 are obtained from this one by flipping the signs of some row and/or column (and by taking permutations of rows and/or columns, according to the definition in use). One conference matrix of order 10 is :\begin{pmatrix}0 & -1 & -1 & +1 & -1 & -1 & -1 & +1 & -1 & -1 \\-1 & 0 & -1 & -1 & -1 & +1 & +1 & -1 & -1 & -1 \\-1 & -1 & 0 & -1 & +1 & -1 & +1 & +1 & +1 & -1 \\ +1 & -1 & -1 & 0 & +1 & +1 & +1 & +1 & -1 & +1 \\-1 & -1 & +1 & +1 & 0 & -1 & +1 & -1 & -1 & +1 \\-1 & +1 & -1 & +1 & -1 & 0 & +1 & +1 & +1 & +1 \\-1 & +1 & +1 & +1 & +1 & +1 & 0 & +1 & -1 & -1 \\ +1 & -1 & +1 & +1 & -1 & +1 & +1 & 0 & +1 & -1 \\-1 & -1 & +1 & -1 & -1 & +1 & -1 & +1 & 0 & +1 \\-1 & -1 & -1 & +1 & +1 & +1 & -1 & -1 & +1 & 0\end{pmatrix}. ==Skew-symmetric conference matrices==
Skew-symmetric conference matrices
Skew-symmetric matrices can also be produced by the Paley construction. Let q be a prime power with residue 3 mod 4. Then there is a Paley digraph of order q which leads to a skew-symmetric conference matrix of order n = q + 1. The matrix is obtained by taking for S the q × q matrix that has a +1 in position (i, j) and −1 in position (j, i) if there is an arc of the digraph from i to j, and zero diagonal. Then C constructed as above from S, but with the first row all negative, is a skew-symmetric conference matrix. This construction solves only a small part of the problem of deciding for which evenly even numbers n there exist skew-symmetric conference matrices of order n. ==Generalizations==
Generalizations
Sometimes a conference matrix of order n is just defined as a weighing matrix of the form W(n, n−1), where W(n,w) is said to be of weight w > 0 and order n if it is a square matrix of size n with entries from {−1, 0, +1} satisfying WW T = wI. ==Telephone conference circuits==
Telephone conference circuits
Belevitch obtained complete solutions for conference matrices for all values of n up to 38 and provided circuits for some of the smaller matrices. An ideal conference network is one where the loss of signal is entirely due to the signal being split between multiple conference subscriber ports. That is, there are no dissipation losses within the network. The network must contain ideal transformers only and no resistances. An n-port ideal conference network exists if and only if there exists a conference matrix of order n. For instance, a 3-port conference network can be constructed with the well-known hybrid transformer circuit used for 2-wire to 4-wire conversion in telephone handsets and line repeaters. However, there is no order 3 conference matrix and this circuit does not produce an ideal conference network. A resistance is needed for matching which dissipates signal, or else signal is lost through mismatch. As mentioned above, a necessary condition for a conference matrix to exist is that n−1 must be the sum of two squares. Where there is more than one possible sum of two squares for n−1 there will exist multiple essentially different solutions for the corresponding conference network. This situation occurs at n of 26 and 66. The networks are particularly simple when n−1 is a perfect square (n = 2, 10, 26, ...). ==Notes==
Source: Wikipedia ↗
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