In mathematics the Petersson inner product is an inner product defined on the space of entire modular forms. It was introduced by the German mathematician Hans Petersson.
Let be the space of entire modular forms of weight and the space of cusp forms.
The mapping ,
is called Petersson inner product, where
is a fundamental region of the modular group and for
is the hyperbolic volume form.
The integral is absolutely convergent and the Petersson inner product is a positive definite Hermitian form.
For the Hecke operators , and for forms of level , we have:
This can be used to show that the space of cusp forms of level has an orthonormal basis consisting of simultaneous eigenfunctions for the Hecke operators and the Fourier coefficients of these forms are all real.
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In mathematics, in particular in the theory of modular forms, a Hecke operator, studied by Erich Hecke (1937a,1937b), is a certain kind of "averaging" operator that plays a significant role in the structure of vector spaces of modular forms and more general automorphic representations.
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In mathematics, modular forms are particular complex analytic functions on the upper half-plane of interest in complex analysis and number theory. When reduced modulo a prime p, there is an analogous theory to the classical theory of complex modular forms and the p-adic theory of modular forms.