The density of uncyclic matrices

Abstract: An element $X$ in the algebra ${\rm M}(n,\mathbb{F})$ of all $n\times n$ matrices over a field $\mathbb{F}$ is said to be $f$-cyclic if the underlying vector space considered as an $\mathbb{F}[X]$-module has at least one cyclic primary component. These are the matrices considered to be good' in the Holt-Rees version of Norton's irreducibility test in the MeatAxe algorithm. We prove that, for any finite field $\mathbb{F}_q$, the proportion of matrices in ${\rm M}(n,\mathbb{F}_q)$ that arenot good' decays exponentially to zero as the dimension $n$ approaches infinity. Turning this around, we prove that the density of good' matrices in ${\rm M}(n,\mathbb{F}_q)$ for the MeatAxe depends on the degree, showing that it is at least $1-\frac2q(\frac{1}{q}+\frac{1}{q^2}+\frac{2}{q^3})^n$ for $q\geq4$. We conjecture that the density is at least $1-\frac1q(\frac{1}{q}+\frac{1}{2q^2})^n$ for all $q$ and $n$, and confirm this conjecture for dimensions $n\leq 37$. Finally we give a one-sided Monte Carlo algorithm called IsfCyclic to test whether a matrix isgood', at a cost of ${\rm O}({\rm Mat}(n)\log n)$ field operations, where ${\rm Mat}(n)$ is an upper bound for the number of field operations required to multiply two matrices in ${\rm M}(n,\mathbb{F}_q)$.