Wave Packets and Eigenvalue Estimates for Limiting Operators on the Disk

Abstract

We study two-dimensional spatio-spectral limiting operators \[ TR := PD(R) BS PD(R) : L2(R2) → L2(R2), \] where D(R) is a disk of radius R>1, S⊂R2 is a domain with well-shaped boundary, PD(R) is the orthogonal projection on the subspace of functions supported on D(R), and BS is the orthogonal projection on the subspace of functions whose Fourier transform is supported on S. We construct a disk-adapted wave-packet frame for L2(D(R)) with frame bounds uniform in R using Gevrey-s cutoffs (s>1) to obtain near-exponential Fourier localization. Exploiting these localization estimates, we bound the size of the eigenvalue plunge-region for TR and prove that for each s>1 and each ∈(0,1/2), \[ \#\k : λk(TR)∈(,1-)\ = O\!(R ((R/))1+2s), \] with constants depending on s and the geometric parameters of S. This bound improves existing plunge-region estimates in the classical setting where both domains are disks, when scales like R- for a fixed > 0. By an affine transformation, the same result holds if D(R) is a scaled ellipse.