Book contents
- Front Matter
- Contents
- Preamble
- Notation
- I Hypotheses, automorphic forms, constant terms
- II Decomposition according to cuspidal data
- III Hilbertian operators and automorphic forms
- III.1. Hilbertian operators
- III.2. A decomposition of the space of automorphic forms
- III.3. Cuspidal exponents and square integrable automorphic forms
- IV Continuation of Eisenstein series
- V Construction of the discrete spectrum via residues
- Appendix I Lifting of unipotent subgroups into a central extension
- Appendix II Automorphic forms and Eisenstein series over a function field
- Appendix III On the discrete spectrum of G2
- Appendix IV Non-connected groups
- Bibliography
- Index
III.1. - Hilbertian operators
from III - Hilbertian operators and automorphic forms
Published online by Cambridge University Press: 22 September 2009
- Front Matter
- Contents
- Preamble
- Notation
- I Hypotheses, automorphic forms, constant terms
- II Decomposition according to cuspidal data
- III Hilbertian operators and automorphic forms
- III.1. Hilbertian operators
- III.2. A decomposition of the space of automorphic forms
- III.3. Cuspidal exponents and square integrable automorphic forms
- IV Continuation of Eisenstein series
- V Construction of the discrete spectrum via residues
- Appendix I Lifting of unipotent subgroups into a central extension
- Appendix II Automorphic forms and Eisenstein series over a function field
- Appendix III On the discrete spectrum of G2
- Appendix IV Non-connected groups
- Bibliography
- Index
Summary
A family of operators
Fix an equivalence class of pairs (M, ℬ) where M is a standard Levi of G and ℬ an orbit under XGM of irreducible cuspidal automorphic representations of M, for the equivalence relation defined in II.2.1. We denote by the set of pairs (M,π) where π is an irreducible cuspidal automorphic representation of M such that if ℬ is the orbit of π, then (M, ℬ) ∈. Denote by ξ the character of ZG which is the restriction to ZG of the central character of π for any pair (M,π) ∈. Fix a real number R such that if (M, ℬ) ∈ ξ and if P is the standard parabolic subgroup of G of Levi M then R Ⅱ ρP Ⅱ; the norm Ⅱρp Ⅱ is the same for all pairs (M, ℬ) ∈ 3E. Denote by Θ R the space generated by the functions θφ for φ ∈PR(M ℬ) and (M, ℬ) ∈ In the case where ξ is unitary, we write L for its closure in L2(G(k)\G) ξ (the space L2 is independent of R).
Let us introduce the space whose elements are the functions ƒ defined on∊that associate with (M,π) an element ƒ (M,π) ∈ EndM (A0(M(k)\M)π) (see 1.3.3; this last space is finite-dimensional), and that satisfy: ƒ is holomorphic on R.
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- Spectral Decomposition and Eisenstein SeriesA Paraphrase of the Scriptures, pp. 109 - 115Publisher: Cambridge University PressPrint publication year: 1995