Diophantine approximation by almost equilateral triangles

Abstract

A two-dimensional continued fraction expansion is a map μ assigning to every x ∈ R2 Q2 a sequence μ(x)=T0,T1,… of triangles Tn with vertices xni=(pni/dni,qni/dni)∈ Q2, dni>0, pni, qni, dni∈ Z, i=1,2,3, such that eqnarray* (matrix pn1& qn1 &dn1\\ pn2& qn2 &dn2\\ pn3& qn3 &dn3 matrix ) = 1\,\,\, \,\,\,and\,\,\,\,\,\, n Tn = \x\. eqnarray* We construct a two-dimensional continued fraction expansion μ* such that for densely many (Turing computable) points x the vertices of the triangles of μ(x) strongly converge to x. Strong convergence depends on the value of n ∞Σi=13(x,xni)(2dn1dn2dn3)-1/2, ("dist" denoting euclidean distance) which in turn depends on the smallest angle of Tn. Our proofs combine a classical theorem of Davenport Mahler in diophantine approximation, with the algorithmic resolution of toric singularities in the equivalent framework of regular fans and their stellar operations.