English

Harmonic Analysis associated with a discrete Laplacian

Classical Analysis and ODEs 2025-01-03 v2

Abstract

It is well-known that the fundamental solution of ut(n,t)=u(n+1,t)2u(n,t)+u(n1,t),nZ, u_t(n,t)= u(n+1,t)-2u(n,t)+u(n-1,t), \quad n\in\mathbb{Z}, with u(n,0)=δnmu(n,0) =\delta_{nm} for every fixed mZm \in\mathbb{Z}, is given by u(n,t)=e2tInm(2t)u(n,t) = e^{-2t}I_{n-m}(2t), where Ik(t)I_k(t) is the Bessel function of imaginary argument. In other words, the heat semigroup of the discrete Laplacian is described by the formal series Wtf(n)=mZe2tInm(2t)f(m). W_tf(n) = \sum_{m\in\mathbb{Z}} e^{-2t} I_{n-m}(2t) f(m). By using semigroup theory, this formula allows us to analyze some operators associated with the discrete Laplacian. In particular, we obtain the maximum principle for the discrete fractional Laplacian, weighted p(Z)\ell^p(\mathbb{Z})-boundedness of conjugate harmonic functions, Riesz transforms and square functions of Littlewood-Paley. Interestingly, it is shown that the Riesz transforms coincide essentially with the so called discrete Hilbert transform defined by D. Hilbert at the beginning of the XX century. We also see that these Riesz transforms are limits of the conjugate harmonic functions. The results rely on a careful use of several properties of Bessel functions.

Keywords

Cite

@article{arxiv.1401.2091,
  title  = {Harmonic Analysis associated with a discrete Laplacian},
  author = {Ó. Ciaurri and T. A. Gillespie and L. Roncal and J. L. Torrea and J. L. Varona},
  journal= {arXiv preprint arXiv:1401.2091},
  year   = {2025}
}

Comments

21 pages. To appear in Journal d'Analyse Mathematique

R2 v1 2026-06-22T02:42:19.032Z