English

Hyperbolic Fourier series

Analysis of PDEs 2023-07-06 v2

Abstract

In this article we explain the essence of the interrelation described in [PNAS 118, 15 (2021)] on how to write explicit interpolation formula for solutions of the Klein-Gordon equation by using the recent Fourier pair interpolation formula of Viazovska and Radchenko from [Publ Math-Paris 129, 1 (2019)]. We construct explicitly the sequence in L1(R)L^1 (\mathbb{R} ) which is biorthogonal to the system 11, exp(iπnx)\exp ( i \pi n x), exp(iπn/x)\exp ( i \pi n/ x), nZ{0}n \in \mathbb{Z} \setminus \{0\}, and show that it is complete in L1(R)L^1 (\mathbb{R}). We associate with each fL1(R,(1+x2)1dx)f \in L^1 (\mathbb{R}, (1+x^2)^{-1} d x) its hyperbolic Fourier series h0(f)+nZ{0}(hn(f)eiπnx+mn(f)eiπn/x)h_{0}(f) + \sum_{n \in \mathbb{Z}\setminus \{0\}}(h_{n}(f) e^{ i \pi n x} + m_{n}(f) e^{-i \pi n / x} ) and prove that it converges to ff in the space of tempered distributions on the real line. Applied to the above mentioned biorthogonal system, the integral transform given by Uφ(x,y):=Rφ(t)exp(ixt+iy/t)dtU_{\varphi} (x, y):= \int_{\mathbb{R}} \varphi (t) \exp \left( i x t + i y / t \right) d t , for φL1(R)\varphi \in L^{1} (\mathbb{R}) and (x,y)R2(x, y) \in \mathbb{R}^{2}, supplies interpolating functions for the Klein-Gordon equation.

Keywords

Cite

@article{arxiv.2110.00148,
  title  = {Hyperbolic Fourier series},
  author = {Andrew Bakan and Haakan Hedenmalm and Alfonso Montes-Rodriguez and Danylo Radchenko and Maryna Viazovska},
  journal= {arXiv preprint arXiv:2110.00148},
  year   = {2023}
}

Comments

123 pages, 3 figures

R2 v1 2026-06-24T06:32:33.917Z