The densest matroids in minor-closed classes with exponential growth rate

TL;DR

This paper characterizes the exact form of the maximum size of simple matroids in minor-closed classes with exponential growth, providing formulas and conditions for large ranks.

Contribution

It proves a precise formula for the growth rate function in exponential cases and characterizes the matroids attaining this growth, with computable parameters.

Findings

The growth rate function follows a specific exponential formula for large n.

Constants k and d in the formula are determined by finite computations.

Characterization of matroids that attain the maximum size for large n.

Abstract

The $\mathit{growth\ rate\ function}$ for a nonempty minor-closed class of matroids $\mathcal{M}$ is the function $h_{\mathcal{M}}(n)$ whose value at an integer $n \ge 0$ is defined to be the maximum number of elements in a simple matroid in $\mathcal{M}$ of rank at most $n$. Geelen, Kabell, Kung and Whittle showed that, whenever $h_{\mathcal{M}}(2)$ is finite, the function $h_{\mathcal{M}}$ grows linearly, quadratically or exponentially in $n$ (with base equal to a prime power $q$), up to a constant factor. We prove that in the exponential case, there are nonnegative integers $k$ and $d \le \tfrac{q^{2k}-1}{q-1}$ such that $h_{\mathcal{M}}(n) = \frac{q^{n+k}-1}{q-1} - qd$ for all sufficiently large $n$, and we characterise which matroids attain the growth rate function for large $n$. We also show that if $\mathcal{M}$ is specified in a certain `natural' way (by intersections of classes of matroids representable over different finite fields and/or by excluding a finite set of minors), then the constants $k$ and $d$, as well as the point that `sufficiently large' begins to apply to $n$, can be determined by a finite computation.