Dimension theory of inhomogeneous Diophantine approximation with matrix sequences
Abstract
In this paper, we investigate the Hausdorff dimension of naturally occurring sets of inhomogeneous well-approximable points with a sequence of real invertible matrices A=(An)n∈N. Specifically, for a given point y∈ [0,1)d and a function : N R+, we study the limsup set \[ W(A,, y) =\x∈ [0,1)d Anx~(~1)∈ B(y, (n)) ~ for~ infinitely ~many~n∈N\.\] The upper and lower bounds on the Hausdorff dimension of W(A,, y) are determined by involving the singular values of An and the successive minima of the lattice An-1Zd, and both bounds are shown to be attainable for some matrices. Within this framework, we unify the problem of shrinking target sets and recurrence sets, establishing the Hausdorff dimensions for such limsup sets. As applications, our corresponding upper bounds for shrinking target and recurrence sets essentially improve those appearing in the present literature. Furthermore, explicit Hausdorff dimension formulas are derived for shrinking targets and recurrence sets associated with concrete classes of matrices. We extend the Mass Transference Principle for rectangles of Li-Liao-Velani-Wang-Zorin (Adv. Math., 2025) to rectangles under local isometries. This generalization yields a general lower bound for the Hausdorff dimension of W(A,, y).
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