A Generalized Fourier Transform and a Smooth Analogue of Dunkl Operators

Abstract

We introduce a deformation of the Fourier transform on RN arising from a representation-theoretic construction associated with SL(2,R) × O(N) that still admits an underlying degree-one operator structure. More precisely, we construct a generalized Fourier transform Fb, a non-local deformation Hb of the Laplacian , and operators Db,n deforming the partial derivatives ∂∂ xn. We show that the operators Db,n and xn are compatible with the SL(2,R)-representation in a way parallel to the classical case: for each n, the space spanned by xn and Db,n carries the standard representation of SL(2,R); in particular, the generalized Fourier transform Fb interchanges Db,n and xn, and the sl2-triple is recovered from quadratic expressions in these operators. We also establish the inversion formula for Fb and give explicit formulas for both Fb and Db,n. In particular, Fb admits an explicit integral kernel representation, and Db,n is expressed as the sum of a differential term and a spherical integral term. Our construction might be viewed as a continuous analogue of Dunkl theory, with O(N) playing the role of a reflection group.