Rational points in Cantor sets and spectral eigenvalue problem for self-similar spectral measures
Abstract
Given q∈ N 3 and a finite set A⊂Q, let K(q,A)= \Σi=1∞ aiqi:ai ∈ A ~∀ i∈ N \. For p∈N 2 let Dp⊂R be the set of all rational numbers having a finite p-ary expansion. We show in this paper that for p ∈ N 2 with (p,q)=1, the intersection Dp K(q, A) is a finite set if and only if H K(q, A)<1, which is also equivalent to the fact that the set K(q, A) has no interiors. We apply this result to study the spectral eigenvalue problem. For a Borel probability measure μ on R, a real number t∈ R is called a spectral eigenvalue of μ if both E() =\ e2 π i λ x: λ ∈ \ and E(t) = \ e2 π i tλ x: λ ∈ \ are orthonormal bases in L2(μ) for some ⊂ R. For any self-similar spectral measure generated by a Hadamard triple, we provide a class of spectral eigenvalues which is dense in [0,+∞), and show that every eigen-subspace associated with these spectral eigenvalues is infinite.
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