English

Wave Packets and Eigenvalue Estimates for Limiting Operators on the Disk

Functional Analysis 2026-01-30 v1 Classical Analysis and ODEs Spectral Theory

Abstract

We study two-dimensional spatio-spectral limiting operators TR:=PD(R)BSPD(R):L2(R2)L2(R2), T_R := P_{D(R)} B_S P_{D(R)} : L^2(\mathbb{R}^2) \rightarrow L^2(\mathbb{R}^2), where D(R)D(R) is a disk of radius R>1R>1, SR2S\subset\mathbb{R}^2 is a domain with well-shaped boundary, PD(R)P_{D(R)} is the orthogonal projection on the subspace of functions supported on D(R)D(R), and BSB_S is the orthogonal projection on the subspace of functions whose Fourier transform is supported on SS. We construct a disk-adapted wave-packet frame for L2(D(R))L^2(D(R)) with frame bounds uniform in RR using Gevrey-ss cutoffs (s>1s>1) to obtain near-exponential Fourier localization. Exploiting these localization estimates, we bound the size of the eigenvalue plunge-region for TRT_R and prove that for each s>1s>1 and each ε(0,1/2)\varepsilon\in(0,1/2), #{k:λk(TR)(ε,1ε)}=O ⁣(R(log(R/ε))1+2s), \#\{k : \lambda_k(T_R)\in(\varepsilon,1-\varepsilon)\} = O\!\left(R (\log(R/\varepsilon))^{1+2s}\right), with constants depending on ss and the geometric parameters of SS. This bound improves existing plunge-region estimates in the classical setting where both domains are disks, when ε\varepsilon scales like RνR^{-\nu} for a fixed ν>0\nu > 0. By an affine transformation, the same result holds if D(R)D(R) is a scaled ellipse.

Cite

@article{arxiv.2601.21224,
  title  = {Wave Packets and Eigenvalue Estimates for Limiting Operators on the Disk},
  author = {Kevin Hughes and Arie Israel and Azita Mayeli},
  journal= {arXiv preprint arXiv:2601.21224},
  year   = {2026}
}

Comments

30 pages; 1 table; 1 figure

R2 v1 2026-07-01T09:24:56.885Z