Polynomials Counting Group Colorings in Graphs

Abstract

Jaeger et al. in 1992 introduced group coloring as the dual concept to group connectivity in graphs. Let A be an additive Abelian group, f: E(G) A and D an orientation of a graph G. A vertex coloring c:V(G) A is an (A, f)-coloring if c(v)-c(u) f(e) for each oriented edge e=uv from u to v under D. Kochol recently introduced the assigning polynomial to count nowhere-zero chains in graphs--nonhomogeneous analogues of nowhere-zero flows in Kochol2022, and later extended the approach to regular matroids in Kochol2024. Motivated by Kochol's work, we define the α-compatible graph and the cycle-assigning polynomial P(G, α; k) at k in terms of α-compatible spanning subgraphs, where α is an assigning of G from its cycles to \0,1\. We prove that P(G,α;k) evaluates the number of (A,f)-colorings of G for any Abelian group A of order k and f:E(G) A such that the assigning αD,f given by f equals α. Such an assigning is admissible. Based on Kochol's work, we derive that k-c(G)P(G,α;k) is a polynomial enumerating (A,f)-tensions and counting specific nowhere-zero chains. Furthermore, by extending Whitney's broken cycle concept to broken compatible cycles, we show that the absolute value of the coefficient of k|V(G)|-i in P(G,α;k) associated with admissible assignings α equals the number of α-compatible spanning subgraphs that have i edges and contain no broken α-compatible cycles. According to the combinatorial explanation, we establish a unified order-preserving relation from admissible assignings to cycle-assigning polynomials, and further show that for any admissible assigning α of G with α(e)=1 for every loop e, the coefficients of P(G,α;k) are nonzero and alternate in sign.