New Kronecker-Weyl type equidistribution results and diophantine approximation

Abstract: An interesting result of Veech more than 50 years ago is a parity, or mod $2$, version of the Kronecker--Weyl equidistribution theorem concerning the irrational rotation sequence ${q\alpha}$, $q=0,1,2,3,\ldots.$ If $\alpha$ is badly approximable and $b\in(0,1)$ satisfies $b\ne{m\alpha}$ for any $m\in\mathbb{Z}$, then the parity of cardinalities of the sets ${1\le q\le N:{q\alpha}\in[0,b)}$ as $N\to\infty$ is evenly distributed. We first answer a question of Veech and establish a stronger form of the mod $n$ analog of his result (Theorem 3.1). Furthermore, for irrational $\alpha$ and $b={m\alpha}$ for some $m\in\mathbb{N}$, we give a simple yet precise characterization of those cases that give rise to even distribution (Theorem 2.1). We also obtain time-quantitative description of some very striking violations of uniformity -- this part is particularly number theoretic in nature, and involves Ostrowski representations of positive integers and $\alpha$-expansions of real numbers (Theorem 3.4). The Veech discrete $2$-circle problem can also be visualized as a problem that concerns $1$-direction geodesic flow on a surface obtained by modifying the surface comprising two side-by-side squares by the inclusion of symmetric barriers and gates on the vertical edges, with appropriate modification of the vertical edge identifications. We establish a far-reaching generalization of this case to ones that concern $1$-direction geodesic flow on surfaces obtained by modifying a finite square tiled translation surface in analogous but not necessarily symmetric ways (Theorem 3.2).