Upper bounds and spectrum for approximation exponents for subspaces of Rn

Abstract

This paper uses W. M. Schmidt's idea formulated in 1967 to generalise the classical theory of Diophantine approximation to subspaces of Rn. Given two subspaces of Rn A and B of respective dimensions d and e with d+e≤slant n, the proximity between A and B is measured by t=(d,e) canonical angles 0≤slant θ1≤slant ·s≤slant θt≤slant π/2; we set j(A,B)=θj. If B is a rational subspace, his complexity is measured by its height H(B)=covol(Bn). We denote by μn(A e)j the exponent of approximation defined as the upper bound (possibly equal to +∞) of the set of β>0 such that for infinitely many rational subspaces B of dimension e, the inequality j(A,B)≤slant H(B)-β holds. We are interested in the minimal value μn(d e)j taken by μn(A e)j when A ranges through the set of subspaces of dimension d of Rn such that for all rational subspaces B of dimension e one has (A B)<j. We show that if A is included in a rational subspace F of dimension k, its exponent in Rn is the same as its exponent in Rk via a rational isomorphism Fk. This allows us to deduce new upper bounds for μn(d e)j. We also study the values taken by μn(A e)e when A is a subspace of Rn satisfying (A B)<e for all rational subspaces B of dimension e.

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