Cyclic Sieving of Multisets with Bounded Multiplicity and the Frobenius Coin Problem
Abstract
The two subjects in the title are related via the specialization of symmetric polynomials at roots of unity. Let f(z1,…,zn)∈Z[z1,…,zn] be a symmetric polynomial with integer coefficients and let ω be a primitive dth root of unity. If d|n or d|(n-1) then we have f(1,ω,…,ωn-1)∈Z. If d|n then of course we have f(ω,ω2,…,ωn)=f(1,ω,…,ωn-1)∈Z, but when d|(n+1) we also have f(ω,ω2,…,ωn)∈Z. We investigate these three families of integers in the case f=hk(b), where hk(b) is the coefficient of tk in the generating function Πi=1n (1+zit+·s+(zit)b-1). These polynomials were previously considered by several authors. They interpolate between the elementary symmetric polynomials (b=2) and the complete homogeneous symmetric polynomials (b∞). When (b,d)=1 with d|n or d|(n-1) we find that the integers hk(b)(1,ω,…,ωn-1) are related to cyclic sieving of multisets with multiplicities bounded above by b, generalizing the well-known cyclic sieving results for sets (b=2) and multisets (b ∞). When (b,d)=1 and d|(n+1) we find that the integers hk(b)(ω,ω2,…,ωn) are related to the Frobenius coin problem with two coins. The case (b,d)≠ 1 is more complicated. At the end of the paper we combine these results with the expansion of hk(b) in various bases of the ring of symmetric polynomials.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.