Certain Fourier Operators and their Associated Poisson Summation Formulae on GL1

Abstract

In this paper, we explore a possibility to utilize harmonic analysis on 1 to understand Langlands automorphic L-functions in general, as a vast generalization of the pioneering work of J. Tate. For a split reductive group G over a number field k, let G() be its complex dual group and be an n-dimensional complex representation of G(). For any irreducible cuspidal automorphic representation of G(), where is the ring of adeles of k, we introduce the space ,(×) of (,)-Schwartz functions on × and (,)-Fourier operator ,, that takes ,(×) to ,(×), where is the contragredient of . By assuming the local Langlands functoriality for the pair (G,), we show that the (,)-theta functions \[ ,(x,φ):=Σ∈ k×φ( x) \] converges absolutely for all φ∈,(×), and state conjectures on (σ,)-Poisson summation formula on 1. Then we prove conjectures when G=n and is the standard representation of n() . The proof uses substantially the local theory of Godement-Jacquet for the standard L-functions of n and the Poisson summation formula for the classical Fourier transform on affine spaces. As an application, we provide a spectral interpretation of the critical zeros of the standard L-functions L(s,π×) for any irreducible cuspidal automorphic representation π of n() and idele class character of k, which is a reformulation in the adelic framework of the work of A. Connes and is an extension from the Hecke L-functions L(s,) to the automorphic L-functions L(s,π×).