Generalized Riemann Functions, Their Weights, and the Complete Graph
Abstract
By a {\em Riemann function} we mean a function such that is equals for sufficiently small, and equals for a constant, , for sufficiently large. By adding to the Baker-Norine rank function of a graph, one gets an equivalent Riemann function, and similarly for related rank functions. To each Riemann function we associate a related function via M\"obius inversion that we call the {\em weight} of the Riemann function. We give evidence that the weight seems to organize the structure of a Riemann function in a simpler way: first, a Riemann function satisfies a Riemann-Roch formula iff its weight satisfies a simpler symmetry condition. Second, we will calculate the weight of the Baker-Norine rank for certain graphs and show that the weight function is quite simple to describe; we do this for graphs on two vertices and for the complete graph. For the complete graph, we build on the work of Cori and Le Borgne who gave a linear time method to compute the Baker-Norine rank of the complete graph. The associated weight function has a simple formula and is extremely sparse (i.e., mostly zero). Our computation of the weight function leads to another linear time algorithm to compute the Baker-Norine rank, via a formula likely related to one of Cori and Le Borgne, but seemingly simpler, namely Our study of weight functions leads to a natural generalization of Riemann functions, with many of the same properties exhibited by Riemann functions.
Keywords
Cite
@article{arxiv.2205.13592,
title = {Generalized Riemann Functions, Their Weights, and the Complete Graph},
author = {Nicolas Folinsbee and Joel Friedman},
journal= {arXiv preprint arXiv:2205.13592},
year = {2022}
}