English

Computing the Laplace eigenvalue and level of Maass cusp forms

Number Theory 2016-11-09 v1

Abstract

Let ff be a primitive Maass cusp form for a congruence subgroup Γ0(D)\Gamma_0(D) \subset SL(2,Z2,\mathbb{Z}) and λf(n)\lambda_f(n) its nn-th Fourier coefficient. In this paper it is shown that with knowledge of only finitely many λf(n)\lambda_f(n) one can often solve for the level DD, and in some cases, estimate the Laplace eigenvalue to arbitrarily high precision. This is done by analyzing the resonance and rapid decay of smoothly weighted sums of λf(n)e(αnβ)\lambda_f(n)e(\alpha n^{\beta}) for Xn2XX \leq n \leq 2X and any choice of αR\alpha \in \mathbb{R}, and β>0\beta>0. The methods include the Voronoi summation formula, asymptotic expansions of Bessel functions, weighted stationary phase, and computational software. These algorithms manifest the belief that the resonance and rapid decay nature uniquely characterizes the underlying cusp form. They also demonstrate that the Fourier coefficients of a cusp form contain all arithmetic information of the form.

Keywords

Cite

@article{arxiv.1611.02668,
  title  = {Computing the Laplace eigenvalue and level of Maass cusp forms},
  author = {Paul Savala},
  journal= {arXiv preprint arXiv:1611.02668},
  year   = {2016}
}
R2 v1 2026-06-22T16:46:07.388Z