Necklaces over a group with identity product
Abstract
We address two variants of the classical necklace counting problem from enumerative combinatorics. In both cases, we fix a finite group G and a positive integer n. In the first variant, we count the ``identity-product n-necklaces'' -- that is, the orbits of n-tuples (a1, a2, …, an) ∈ Gn that satisfy a1 a2 ·s an = 1 under cyclic rotation. In the second, we count the orbits of all n-tuples (a1, a2, …, an) ∈ Gn under cyclic rotation and left multiplication (i.e., the operation of G on Gn given by h · (a1, a2, …, an) = (ha1, ha2, …, han)). We prove bijectively that both answers are the same, and express them as a sum over divisors of n. Consequently, we generalize the first problem to n-necklaces whose product of entries lies in a given subset of G (closed under conjugation), and we connect a particular case to the enumeration of irreducible polynomials over a finite field with given degree and second-highest coefficient 0.
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