For bipermutive CA of diameter d generating Latin squares of order 2^{d-1}, the main diagonal is a transversal exactly when the local rule induces an invertible periodic-boundary CA on d-1 cells; exhaustive search shows d=6 is the smallest such diameter for nonlinear rules.
Constructing Orthogonal Latin Squares from Linear Cellular Automata
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abstract
We undertake an investigation of combinatorial designs engendered by cellular automata (CA), focusing in particular on orthogonal Latin squares and orthogonal arrays. The motivation is of cryptographic nature. Indeed, we consider the problem of employing CA to define threshold secret sharing schemes via orthogonal Latin squares. We first show how to generate Latin squares through bipermutive CA. Then, using a characterization based on Sylvester matrices, we prove that two linear CA induce a pair of orthogonal Latin squares if and only if the polynomials associated to their local rules are relatively prime.
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On the transversals of Latin squares generated by nonlinear bipermutive cellular automata
For bipermutive CA of diameter d generating Latin squares of order 2^{d-1}, the main diagonal is a transversal exactly when the local rule induces an invertible periodic-boundary CA on d-1 cells; exhaustive search shows d=6 is the smallest such diameter for nonlinear rules.