On Matrix Product Factorization of Cayley graphs
Abstract
We study when the adjacency matrix of a Cayley graph factors as the product of two adjacency matrices of Cayley graphs. Let G be a finite group and let U⊂eq G \e\ be symmetric. Writing A(G;U) for the adjacency matrix of the Cayley graph of G with respect to U, we prove that for symmetric subsets S,T,U of G \e\, A(G;U)=A(G;S)\,A(G;T) if and only if U=ST and each u∈ U has a unique representation u=st, equivalently (Σs∈ Ss)(Σt∈ Tt)=Σu∈ Uu in the group algebra. When S,T,U are unions of conjugacy classes, this is characterized character-theoretically by (U)=(S)(T)/(1) for all ∈Irr(G). In addition, for abelian groups, we identify A(G;S)A(G;T) with the 0\!-\!1 convolution 1S*1T, so factorability is equivalent to (S,T) being a Sidon pair, i.e., (S-S)(T-T)=\0\. For cyclic groups, we reformulate factorability via mask polynomials and reduce to prime-power components using the Chinese Remainder Theorem. We also analyze dihedral groups D2n, presenting infinite families of factorable generating sets, and give explicit constructions of subsets whose Cayley graphs do and do not admit such factorizations.
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