Formal self-duality and numerical self-duality for symmetric association schemes
Abstract
Let X = (X, \Ri\i=0d) denote a symmetric association scheme. Fix an ordering \Ei\i=0d of the primitive idempotents of X, and let P (resp.\ Q) denote the corresponding first eigenmatrix (resp.\ second eigenmatrix) of X. The scheme X is said to be formally self-dual (with respect to the ordering \Ei\i=0d) whenever P=Q. We define X to be numerically self-dual (with respect to the ordering \Ei\i=0d) whenever the intersection numbers and Krein parameters satisfy phi,j =qhi,j for 0 ≤ h,i,j ≤ d. It is known that with respect to the ordering \Ei\i=0d, formal self-duality implies numerical self-duality. This raises the following question: is it possible that with respect to the ordering \Ei\i=0d, X is numerically self-dual but not formally self-dual? This is possible as we will show. We display an example of a symmetric association scheme and an ordering the primitive idempotents with respect to which the scheme is numerically self-dual but not formally self-dual. We have the following additional results about self-duality. Assume that X is P-polynomial. We show that the following are equivalent: (i) X is formally self-dual with respect to the ordering \Ei\i=0d; (ii) X is numerically self-dual with respect to the ordering \Ei\i=0d. Assume that the ordering \Ei\i=0d is Q-polynomial. We show that the following are equivalent: (i) X is formally self-dual with respect to the ordering \Ei\i=0d; (ii) X is numerically self-dual with respect to the ordering \Ei\i=0d.
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